Dual stent and delivery system, delivery tool apparatus, and method of delivery of dual stents

ABSTRACT

A method, system, or apparatus for stent delivery. Delivering one or more stents with a delivery tool that can include a kinetic transfer of energy to deliver one or more stents. The stents can include a modifiable stent that can change its overall shape and/or dimensions based on pre-configured design parameters. A coil stent that can engage with a vessel that surrounds the modifiable stent forming a dual stent configuration. The coil stent can also include anchor points that allow it to engage with a second vessel securing the first vessel and the second vessel together to aid in the healing process.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present disclosure incorporates by reference in their entirety for all purposes U.S. patent application Ser. No. 16/752,265, filed Jan. 24, 2020 which claims priority from U.S. Provisional Patent Application No. 62/797,932, filed Jan. 28, 2019; U.S. patent application Ser. No. 16/752,315, filed Jan. 24, 2020, which claims priority from U.S. Provisional Patent Application No. 62/797,933, filed Jan. 28, 2019, and U.S. patent application Ser. No. 16/752,343, filed Jan. 24, 2020, which claims priority from U.S. Provisional Patent Application No. 62/797,944, filed Jan. 28, 2019, all of which is incorporated herein by reference in its entirety for all purposes.

The present disclosure incorporates by reference in its entirety for all purposes and claims priority to U.S. Provisional Patent Application No. 63/225,867, filed Jul. 26, 2021.

BACKGROUND Technical Field

The present disclosure relates to dual stents and the delivery of same. More particularly, and not by way of limitation, the present disclosure is directed to a system, apparatus, or method for aiding in healing through the use of dual stents or the delivery of dual stents.

Description of Related Art

There are many different types of surgeries that can be conducted daily in hospitals across the world. One such surgery is free flap reconstruction. Free flap reconstruction is a well-established method of reconstruction of both soft tissue and bone or composite defects in a wide variety of surgeries. Free flaps are used in order of frequency in head and neck reconstruction, breast reconstruction, orthopedic surgery and a variety of other specialties. Head and neck surgery in particular is a heavy user of free flap reconstruction. This is due to the complexity of defects in a critical area where restoration of functions such as deglutition, phonation, and mastication is of paramount importance in addition to cosmesis.

Free flap reconstruction involves the transfer of tissue from a distant part of the body to the area that needs to be reconstructed. The principle in operation behind this concept is that tissues in the body are supplied in a segmental function. That is that a segment of skin subcutaneous tissue fascia muscle bone, or any combination of these can be harvested according to specific location. The transfer of tissue is completed when the free flap vessels (artery and vein) are joined to the donor vessels and then the flap is set into the defect.

Donor vessels are selected from appropriate vessels to match the diameter of the recipient vessels (free flap vessels). In the neck, these are usually branches of the external carotid artery and one of the many veins in the head and neck or the jugular vein itself. Each of the donor vessels are dissected from surrounding tissue, and their edges prepared for anastomosis. In free flap reconstruction, vessels are raised in situ and the vascular supply is dissected out carefully and traumatically. The vascular supply is then sectioned, preferably at a length of vessel that is appropriate for an anastomosis without tension. This is not always possible as different free flaps have different lengths of vessels according to where they are harvested. For example, free rectus vascular pedicle may have a max length of 8 cm, while a radial forearm vascular pedicle may have a max length of 15-20 cm.

Once the vessels are extracted from the appropriate location, the edge preparation begins. The vessel preparation process can take approximately one hour and is performed under optimal conditions with an operating microscope and/or magnifying loops. Considerable skill is required that comes with prolonged surgical training. The anastomoses (joining) themselves are approximately 20 minutes per vessel anastomosis. Venous couplers reduce the amount of time required for venous anastomoses. However, these venous couplers still require suturing for each venous anastomoses, taking considerable time and increasing the time a patient is under anesthesia. There are two general types of anastomoses, an end to end and an end to side. An end-to-end anastomosis is preferred because it is performed rapidly without additional problems and because the vascular dynamics are that of linear flow which gives lesser complication rates. End to end anastomoses account for the majority of vessel joining. However, currently these operations and/or couplings still require significant suturing time, that can lead to other complications.

It would be advantageous to have a system, apparatus, or method that overcomes the disadvantages of the prior art. The present disclosure provides such a system, apparatus, or method.

BRIEF SUMMARY

The present disclosure is directed to stent delivery.

Thus, in one aspect, the present disclosure is directed to delivering one or more stents with a delivery tool that can include a kinetic transfer of energy to deliver one or more stents.

In another aspect, the present disclosure is directed to a modifiable stent that can change its overall shape and/or dimensions based on pre-configured design parameters.

In yet another aspect, the present disclosure is directed to a coil stent that can engage with a vessel that surrounds the modifiable stent forming a dual stent configuration. The coil stent an also include anchor points that allow it to engage with a second vessel securing the first vessel and the second vessel together to aid in the healing process.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features believed characteristic of the disclosure are set forth in the appended claims. The disclosure itself, however, as well as a preferred mode of use, further objectives and advantages thereof, will be best understood by reference to the following detailed description of illustrative embodiments when read in conjunction with the accompanying drawings, wherein:

FIG. 1A is a perspective view illustration of a vessel with a modifiable stent received within the vessel.

FIG. 1B is a perspective view illustration of a vessel with a modifiable stent received within the vessel and a coil stent surrounding the vessel and a portion of the modifiable stent.

FIG. 1C is a perspective view illustration of a recipient vessel and a donor vessel being linked by a modifiable stent and a coil stent.

FIG. 2A is a perspective view illustration of a compression tool in an open state.

FIG. 2B is a perspective view illustration of an engagement section of a compression tool in a closed state.

FIG. 3A is a perspective view illustration of a stent delivery system having a recipient vessel, a donor vessel, a modifiable stent, a coil stent, and a compression tool in an open state.

FIG. 3B is a perspective view illustration of a stent delivery system having a recipient vessel, a donor vessel, a modifiable stent, a coil stent, and a compression tool in an closed state.

FIG. 4A is a perspective view illustration of an expansion tool.

FIG. 4B is a perspective view illustration of an engagement section of an expansion tool.

FIG. 5A is a perspective view illustration of stent delivery system engaging with a receiving vessel, donor vessel, through a modifiable stent, a coil stent, and an expansion tool.

FIG. 5B is a perspective view illustration of stent delivery system engaging with a receiving vessel, donor vessel, through a modifiable stent, a coil stent, and an expansion tool in an expanded or open state.

FIG. 6A is a perspective cutaway view illustration of stent delivery system having a combination tool and compression tool engaging with a coil stent and a modifiable stent.

FIG. 6B is a perspective cutaway view illustration of stent delivery system having a combination tool and compression tool engaging with a coil stent and a modifiable stent.

FIG. 7A is a perspective view illustration of a stent delivery system having a donor vessel, a modifiable stent, a coil stent, and a compression tool in an open state.

FIG. 7B is a perspective view illustration of a stent delivery system having a donor vessel, a modifiable stent, a coil stent, and a compression tool in an open state.

FIG. 7C is a perspective view illustration of a stent delivery system having a recipient vessel, a donor vessel, a modifiable stent, a coil stent, and a compression tool in an open state.

FIG. 7D is a perspective view illustration of a stent delivery system having a recipient vessel, a donor vessel, a modifiable stent, a coil stent, and a compression tool in an open state.

FIG. 8A is a perspective view illustration of stent delivery system having a delivery tool and a coil stent.

FIG. 8B is a perspective view illustration of a delivery tool and a coil stent.

FIG. 9A is a perspective view illustration of a dual stent delivery tool.

FIG. 9B is a perspective view illustration of a dual stent delivery tool in a zoomed view of the front section of the dual stent delivery tool.

FIG. 9C is a cross-sectional view illustration of a dual stent delivery tool.

FIG. 10 is an exploded view illustration of a dual stent delivery tool.

FIG. 11A is a partially exploded view illustration of a dual stent delivery tool in a pre-delivery state.

FIG. 11B is a partially exploded view illustration of a dual stent delivery tool in a delivered state.

FIG. 12 is a perspective view illustration of a sheath or cover carrier.

DETAILED DESCRIPTION

An embodiment of the disclosure will now be described. While the present disclosure is related to stents and/or stent delivery, the tools described herein may also be utilized with vessels, arteries, and/or veins. FIG. 1A is a perspective view illustration of a vessel 102 with a modifiable stent 104 received within the vessel 102. The stent system 100 can allow for the engagement of a modified stent 104 with a vessel, such as a donor vessel 102. In at least one embodiment, the stent system 100 can allow for faster engagement of vessels during surgeries. The modifiable stent 104 may comprise a modifiable member 106 and/or a non-modifiable member 108. In at least one example, the modifiable stent 104 can change its diameter and/or radius via the modifiable member(s) 106. The modifiable stent 104 may be modified inward or outward, for example decreasing the diameter or increasing the diameter of the modifiable stent to engage with a vessel, such as a donor vessel 102. In some examples, the length of the modifiable stent 104 can be increased or decreased via the modifiable member(s) 106 and/or non-modifiable member 108.

FIG. 1B is a perspective view illustration of a vessel 102 with a modifiable stent 104 received within the vessel 102 and a coil stent 110 surrounding the vessel 102 and a portion of the modifiable stent 104. The stent system 100 can comprise a modifiable stent 104 and a coil stent 110. The modifiable stent 104 and the modifiable member(s) 106 and/or non-modifiable member(s) 108 can allow for engagement with a donor vessel 102, as discussed with reference to FIG. 1A, and can be utilized in a similar manner. The coil stent 110 can engage with the donor vessel 102. In at least one embodiment, the coil stent 110 can comprise a set of points 112 that allow for coupling of the coil stent 110 to a vessel. The set of points 112 can be coupled to the coupling member(s) 116 that form the coil stent 110. Additionally, the set of points 112 may be comprised of atraumatic point(s) 114A and/or traumatic point(s) 114B.

In at least one example, the coil stent 110 can be placed around or over a donor vessel 102 and the modifiable stent 104. In some examples, the modifiable stent 104 would be modified to engage the donor vessel 102 between the modifiable stent 104 and the coil stent 110, and the coil stent 110 can be utilized to engage with additional vessel(s).

FIG. 1C is a perspective view illustration of a recipient vessel 118 and a donor vessel 102 being linked by a modifiable stent 104 and a coil stent 110. Further to the examples and embodiments illustrated in FIGS. 1A and 1B, the recipient vessel 118 can receive the stent system 100 and the donor vessel 102. Because the modifiable stent 104 and the coil stent 110 engage the donor vessel 102 between them, it allows for the donor vessel 102 and stent system 100 to be placed within a recipient vessel 118. In some examples, after the recipient vessel 118 is engaged with the coil stent 110 of the stent system 100, the modifiable stent 104 may be furthered modified via the modifiable member(s) 106 and/or non-modifiable member(s) 108, allowing the stent system 100 to engage the vessels 102 and 118 to avoid movement after placement. The recipient vessel 118 can also be engaged by the set of points 112 of the coil stent 110. The atraumatic points 114A and/or the traumatic points 114B may be utilized for different flow rates or conditions of the vessels 102/118.

FIG. 2A is a perspective view illustration of a compression tool 220. The compression tool 220 can be utilized to compress one or both of the stents and/or coverings of the stents described in the present disclosure. The compression tool 220 has a first end or engagement section 226 that is opposite and distal from an inflection point 222. The inflection point 222 allows for the spring and/or resistive force that allows the compression tool 220 to remain in an open state 232A when not compressed by a user or external force (not illustrated).

The engagement section 226 and the inflection point 222, in at least one embodiment, can be connected by arms 224A and/or 224B. The arms 224A and 224B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement section 226. The engagement section 226, can have an internal void 230 that is defined by a set of engagement arms 228A, 228B, 228C, 228D, and/or 228E, (collectively, a set of engagement arms 228). The set of engagement arms 228 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure.

In at least one example, the set of engagement arms 228 are elongated structures that are generally perpendicular to the arms 224A/224B. In some examples, the set of engagement arms 228 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). In yet other examples, the set of engagement arms 228 may be upwardly sloped to allow for engagement with one or more stents with external protrusions.

In some examples, the compression tool 220 may be called a tweezer tool because of its similarity in operation to a tweezer. In a similar operation, a user can apply a force to the arms to cause a closing action to occur. When a closing action occurs, the arms move closer together from the starting or open state 232A. Upon releasing or reducing the force, the arms will return to the starting or open state 232A. In at least one example, the compression tool 220 may also include a locking mechanism between the arms that allow it to be locked in an open state 232A or a closed state.

FIG. 2B is a perspective view illustration of an engagement section 226 of a compression tool 220. The compression tool 220 can be utilized to compress one or both of the stents and/or coverings of the stents described in the present disclosure. The compression tool 220 has a first end or engagement section 226 that is opposite and distal from an inflection point. In at least one embedment, the inflection point allows for the spring and/or resistive force that allows the compression tool 220 to return to an open state after being compressed by a user or external force to a closed state 232B. A closed state 232B can be when the arms 224A and/or 224B are touching or within a designed distance from one another. In at least one embodiment, when in a closed state, the arms 224A and 224B are within less than one inch from one another, meaning an open state (shown as 232A in FIG. 2A) is when the arms 224A and 224B are more than one inch from one another.

The engagement section 226, in at least one embodiment, can be connected by arms 224A and/or 224B. The arms 224A/224B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement section 226. The engagement section 226, can have an internal void 230 that is defined by a set of engagement arms 228A, 228B, 228C, 228D, 228E, and/or 228F (collectively, a set of engagement arms 228). The set of engagement arms 228 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure.

In at least one example, the set of engagement arms 228 are elongated structures that are generally perpendicular to the arms 224A/224B. In some examples, the set of engagement arms 228 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). The downwardly sloped set of engagement arms 228 may allow for the engagement section 226 to have a tapered end 234. In yet other examples, the set of engagement arms 228 may be upwardly sloped to allow for engagement with one or more stents with external protrusions, in this example, there may be a tapered end 234 that tapers upwardly from the internal void 230. In at least one example, the flexibility of the arms 224A/224B, and/or engagement arms 228 can be flexible in nature to allow for a compressive force to be applied to said arms that is significant enough to compress the stents but not overcome the design and/or construction of the stent itself. In other words, a compression for can be applied by the arms 224A/224B, and/or engagement arms 228 in such a way that they will not change the shape or design of the stent(s) in their various states.

In some examples, the compression tool 220 may be called a tweezer tool because of its similarity in operation to a tweezer. In a similar operation, a user can apply a force to the arms to cause a closing action to occur. When a closing action occurs, the arms move closer together from the starting or open state 232A. Upon releasing or reducing the force, the arms will return to the starting or open state 232A.

FIG. 3A is a perspective view illustration of a stent delivery system 300 having a recipient vessel 318, a donor vessel 302, a modifiable stent 304, a coil stent 310, and a compression tool 320 in an open state 333A. The stent delivery system 300, in at least one example, provides a user (a medical professional) with the ability to compress one or more stents, such as but not limited to the modifiable stent 304 and/or coil stent 310, for easy of entry and/or placement within one or more vessels such as, but not limited to the donor vessel 302 and/or recipient vessel 318. In some examples, the compression tool 320 engages with one or both stents (illustrated as modifiable stent 304 and/or coil stent 310), to allow for the easy of insertion into one or more vessels (illustrated as recipient vessel 318 and donor vessel 302).

In at least one embodiment, the modifiable stent 304 is formed with a combination of modifiable member(s) 306 and non-modifiable member(s) 308, while in some examples, the modifiable stent 304 may be comprised of only modifiable member(s) 306 or non-modifiable member(s) 308. Additionally, in at least one example, the modifiable stent 304 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 304 to be anchored to a specific location or position within the vessel(s) or lumen.

Similarly, the coil stent 310, in at least one embodiment, is formed with coupling member(s) 316, and has a point set 312. In some examples, the coil stent 310 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 310 to be modified in a similar manner as the modifiable stent 304. While in other examples, the coil stent 310 may be formed from only modifiable member(s). The point set 312 of the coil stent 310 may include atraumatic point(s) 314A and/or traumatic point(s) 314B, individually or in combination, to allow for engagement with one or more vessels, such as but not limited to the recipient vessel 318 and/or donor vessel 302.

In at least one embodiment, the modifiable stent 304 is co-axially located or concentric to the coil stent 310. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 304, in at least one example, is housed within the inner diameter of the coil stent 310. The concentric nature of the stent placements allows for the modifiable stent 304 to expand outwardly, to allow for proper fluid passage through the modifiable stent 304, while the coil stent 310 can engage with the vessels (illustrated as recipient vessel 318 and/or donor vessel 302) to prevent the movement of the modifiable stent 304 and/or the coil stent 310. In some examples, the lack of movement of the stents also allows for quicker healing when their vessels are placed in close proximity.

The engagement section 326, in at least one embodiment, can be connected by arms 324A and/or 324B. The arms 324A/324B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement section 326. The engagement section 326, can have an internal void 330 that is defined by a set of engagement arms 328. The set of engagement arms 328 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure.

In at least one example, the set of engagement arms 328 are elongated structures that are generally perpendicular to the arms 324A/324B. In some examples, the set of engagement arms 328 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). In yet other examples, the set of engagement arms 328 may be upwardly sloped to allow for engagement with one or more stents with external protrusions. In at least one embodiment, the engagement arm(s) 328 and the tapered end 334 allow for a user to more easily engage and/or place the stents within a vessel, such as but not limited to the recipient vessel 318. The tapered end 334 can allow the vessel (represented by recipient vessel 318) to be slid, or eased over the stent(s) without the vessel(s) engaging with the stents.

In some examples, the compression tool 320 may be called a tweezer tool because of its similarity in operation to a tweezer. In a similar operation, a user can apply a force to the arms to cause a closing action to occur. When a closing action occurs, the arms move closer together from the starting or open state 333A. Upon releasing or reducing the force, the arms will return to the starting or open state 333A.

FIG. 3B is a perspective view illustration of a stent delivery system 300 having a recipient vessel 318, a donor vessel 302, a modifiable stent 304, a coil stent 310, and a compression tool 320 in a closed state 333B. The stent delivery system 300, in at least one example, provides a user (a medical professional) with the ability to compress one or more stents, such as but not limited to the modifiable stent 304 and/or coil stent 310, for easy of entry and/or placement within one or more vessels such as, but not limited to the donor vessel 302 and/or recipient vessel 318. In some examples, the compression tool 320 engages with one or both of the stents (illustrated as modifiable stent 304 and/or coil stent 310), to allow for the easy of insertion into one or more vessels (illustrated as recipient vessel 318 and donor vessel 302).

In at least one embodiment, the modifiable stent 304 is formed with a combination of modifiable member(s) 306 and non-modifiable member(s) 308, while in some examples, the modifiable stent 304 may be comprised of only modifiable member(s) 306 or non-modifiable member(s) 308. Additionally, in at least one example, the modifiable stent 304 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 304 to be anchored to a specific location or position within the vessel(s) or lumen.

Similarly, the coil stent 310, in at least one embodiment, is formed with coupling member(s) 316 and has a point set 312. In some examples, the coil stent 310 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 310 to be modified in a similar manner as the modifiable stent 304, while in other examples, the coil stent 310 may be formed from only modifiable member(s). The point set 312 of the coil stent 310 may include atraumatic point(s) 314A and/or traumatic point(s) 314B, individually or in combination, to allow for engagement with one or more vessels, such as but not limited to the recipient vessel 318 and/or donor vessel 302.

In at least one embodiment, the modifiable stent 304 is co-axially located or concentric to the coil stent 310. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 304, in at least one example, is housed within the inner diameter of the coil stent 310. The concentric nature of the stent placements allows for the modifiable stent 304 to expand outwardly, to allow for proper fluid passage through the modifiable stent 304, while the coil stent 310 can engage with the vessels (illustrated as recipient vessel 318 and/or donor vessel 302) to prevent the movement of the modifiable stent 304 and/or the coil stent 310. In some examples, the lack of movement of the stents also allows for quicker healing when their vessels are placed in close proximity.

The engagement section 326, in at least one embodiment, can be connected by arms 324A and/or 324B. The arms 324A/324B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement section 326. The engagement section 326, can have an internal void 330 (see FIG. 3A) that is defined by a set of engagement arms 328 (see FIG. 3A). The set of engagement arms 328 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure.

In at least one example, the set of engagement arms 328 are elongated structures that are generally perpendicular to the arms 324A/324B. In some examples, the set of engagement arms 328 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). In yet other examples, the set of engagement arms 328 may be upwardly sloped to allow for engagement with one or more stents with external protrusions. In at least one embodiment, the engagement arm(s) 328 and the tapered end 334 shown in FIG. 3A allow for a user to more easily engage and/or place the stents within a vessel, such as but not limited to the recipient vessel 318. The tapered end 334 can allow the vessel (represented by recipient vessel 318) to be slid or eased over the stent(s) without the vessel(s) engaging with the stents.

In some examples, the compression tool 320 may be called a tweezer tool because of its similarity in operation to a tweezer. In a similar operation, a user can apply a force 336 to the arms to cause a closing action 332B to occur. When a closing action 332B occurs, the arms move closer together from the starting or open state illustrated in FIG. 3A. Upon releasing or reducing the force, the arms will return to the starting or open state.

FIG. 4A is a perspective view illustration of an expansion tool 440. The expansion tool 440 may be utilized to expand a vessel to allow for placement of the stents of the present disclosure. The expansion tool 440 has a first end or engagement section 425 that is opposite and distal from an inflection point 422. In some examples, engagement zone 426 may also be referenced as an engagement section 426. The inflection point 422 allows for the spring and/or resistive force that allows the expansion tool 440 to remain in a neutral state 432A when not compressed by a user or external force (not illustrated).

The engagement section 425 and the inflection point 422, in at least one embodiment, can be connected by arms 424A and/or 424B. The arms 424A/424B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress the arms 424A/424B and/or open the engagement zone 425. Transfer arms 438A and/or 438B can allow a for the transfer of the compression or reasonable force applied by a user to extension arms 442A and/or 442B. The transfer arms 438A/438B may be of a length that allows for the closing of the engagement zone 425 when the expansion tool 440 is in a neutral state 432A and are generally perpendicular to the arms 424A/424B and/or extension arms 442A/442B. The extension arms 442A/442B can act as an extension of the arms 424A/424B but are in opposite planes in order to allow for the expansion of the expansion tool 440. For example, arm 424A corresponds to the extension arm 442B, and arm 424B corresponds to extension arm 442A. This cross over is possible because of the transfer arms 438A/438B.

In at least one examples, the engagement zone 425, can have an internal void 430 that is defined by a set of engagement arms 428. The set of engagement arms 428 can have lengths that allow for engagement with various portions of one or both of the stents, and/or a vessel described in the present disclosure. The set of engagement arms 428 can be elongated structures that are generally perpendicular to the arms 424A/424B. In some examples, the set of engagement arms 428 can be downwardly sloped to allow for additional engagement with vessel. In yet other examples, the set of engagement arms 428 may be upwardly sloped to allow for engagement with a vessel via external protrusions. In at least one embodiment, the set of engagement arms 428 have a set of engagement points 444 that can be traumatic or atraumatic to allow for further engagement with a vessel. In some examples, a taper end 434 may be utilized to ease a vessel or other engaged part onto the expansion tool 440.

In some examples, the expansion tool 440 may be called an expander tool because of its similarity in operation to an expander used in orthodontics to push two points away from one another. In a similar operation, a user can apply a force to the arms to cause an opening action to occur. When an opening action occurs, the arms move closer together from the starting or open state 432A, allowing the engagement zone 425 to open. Upon releasing or reducing the force, the arms will return to the starting or open state 432A, and the engagement zone 425 will return to its closed state.

FIG. 4B is a perspective view illustration of an engagement section 426 of an expansion tool 440. The expansion tool 440 may be utilized to expand a vessel to allow for placement of the stents of the present disclosure. The expansion tool 440 has a first end or engagement section 426 that is opposite and distal from an inflection point (illustrated in FIG. 4A). The inflection point allows for the spring and/or resistive force that allows the expansion tool 440 to remain in a neutral state when not compressed by a user or external force (not illustrated) and allows for the expanded state 432B when a user or external force (not illustrated) is applied to the expansion tool 440.

The engagement section 426, in at least one embodiment, may be connected by arms 424A and/or 424B. The arms 424A/424B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress the arms 424A/424B and/or open the engagement zone 426. Transfer arms 438A and/or 438B can allow for the transfer of the compression or reasonable force applied by a user to extension arms 442A and/or 442B. The transfer arms 438A/438B may be of a length that allows for the closing of the engagement zone 426 when the expansion tool 440 is in a neutral state 432A and are generally perpendicular to the longitudinal direction (from the inflection point to the engagement zone 426) of the arms 424A/424B and/or extension arms 442A/442B. In some examples, engagement zone 426 may also be referenced as an engagement section 426. The extension arms 442A/442B can act as an extension of the arms 424A/424B but are in opposite planes in order to allow for the expansion of the expansion tool 440. For example, arm 424A corresponds to the extension arm 442B, and arm 424B corresponds to extension arm 442A. This cross over is possible because of the transfer arms 438A/438B.

In at least one examples, the engagement zone 426, can have an internal void 430 that is defined by a set of engagement arms 428. The set of engagement arms 428 can have lengths that allow for engagement with various portions of one or both of the stents, and/or a vessel described in the present disclosure. The set of engagement arms 428 can be elongated structures that are generally perpendicular to the arms 424A/424B. In some examples, the set of engagement arms 428 can be downwardly sloped to allow for additional engagement with vessel. In yet other examples, the set of engagement arms 428 may be upwardly sloped to allow for engagement with a vessel via external protrusions. In at least one embodiment, the set of engagement arms 428 have a set of engagement points 444 that can be traumatic or atraumatic to allow for further engagement with a vessel. The engagement points 444 may be atraumatic points 446A or traumatic points 446B. For simplicity, atraumatic points 446A are those designed to not pierce or damage a lumen of a vessel, or other body part, while traumatic points 446B may or may not pierce or otherwise damage, non-critically, a lumen of a vessel or other body part. The ability of the expansion tool 440 to engage with lumens of vessels or other body party may increase with the introduction of a flex point 448 that allows a portion of the engagement zone 426 to be flexible in relation to a second portion. For example, the second portion of the engagement zone 426 may be coupled to the extension arm(s) 442A/442B, while the portion that is opposite the flex point 448 and second portion is free to move and can be biased to expand outwardly to allow for better engagement with a vessel, lumen, or body part. In some examples, a taper end 434 may be utilized to ease a vessel or other engaged part onto the expansion tool 440.

In some examples, the expansion tool 440 may be called an expander tool because of its similarity in operation to an expander used in orthodontics to push two points away from one another. In a similar operation, a user can apply a force to the arms to cause an opening action to occur. When an opening action occurs, the arms move closer together from the starting or open state allowing the engagement zone 426 to open when the expansion tool is in an expanded state 432B. Upon releasing or reducing the force keeping the expansion tool in an expanded state 432B, the arms will return to the starting or open state and the engagement zone 426 will return to its closed state.

FIG. 5A is a perspective view illustration of stent delivery system 500 engaging with a receiving vessel and donor vessel, through a modifiable stent, a coil stent, and an expansion tool. The stent delivery system 500, in at least one example, offers a user (medical professional) the ability to expand a vessel, such as, but not limited to, a recipient vessel 518 and/or donor vessel 502, and allows the insertion of one or more stents, such as but not limited to a modifiable stent 504 and/or a coil stent 510. In some examples, the expansion tool 540 engages with the inner diameter or radius of a vessel (sometimes called the lumen) to expand the vessel to a size large enough to allow placement of one or more stents. As illustrated in FIG. 5A, the expansion tool 540 can be placed within the lumen of a vessel (illustrated as recipient vessel 518).

These stents can then engage with the vessel(s) to allow for proper placement. In at least one embodiment, the modifiable stent 504 is formed with a combination of modifiable member(s) 506 and non-modifiable member(s) 508, while in some examples, the modifiable stent 504 may be comprised of only modifiable member(s) 506 or non-modifiable member(s) 508. Additionally, in at least one example, the modifiable stent 504 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 504 to be anchored to a specific location or position within the vessel(s) or lumen.

Similarly, the coil stent 510, in at least one embodiment, is formed with coupling member(s) 516, and has a point set 512. In some examples, the coil stent 510 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 510 to be modified in a similar manner as the modifiable stent 504, while in other examples, the coil stent 510 may be formed from only modifiable member(s). The point set 512 of the coil stent 510 may include atraumatic point(s) 514A and/or traumatic point(s) 514B, individually or in combination, to allow for engagement with one or more vessels, such as but not limited to the recipient vessel 518 and/or donor vessel 502.

In at least one embodiment, the modifiable stent 504 is co-axially located or concentric to the coil stent 510. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 504, in at least one example, is housed within the inner diameter of the coil stent 510. The concentric nature of the stent placements allow for the modifiable stent 504 to expand outwardly, to allow for proper fluid passage through the modifiable stent 504, while the coil stent 510 can engage with the vessels (illustrated as recipient vessel 518 and/or donor vessel 502) to prevent the movement of the modifiable stent 504 and/or the coil stent 510. In some examples, the lack of movement of the stents also allows for quicker healing when their vessels are placed in close proximity.

In at least one example, the engagement zone 526, can have an internal void 530 that is defined by a set of engagement arms 528. The set of engagement arms 528 can have lengths that allow for engagement with various portions of one or both of the stents, and/or a vessel described in the present disclosure. The set of engagement arms 528 can be elongated structures that are generally perpendicular to the arms 524A/524B. In some examples, the set of engagement arms 528 can be downwardly sloped to allow for additional engagement with vessel. In yet other examples, the set of engagement arms 528 may be upwardly sloped to allow for engagement with a vessel via external protrusions. In at least one embodiment, the set of engagement arms 528 have a set of engagement points 544 (not illustrated) that can be traumatic or atraumatic to allow for further engagement with a vessel.

In some examples, the expansion tool 540 may be called an expander tool because of its similarity in operation to an expander used in orthodontics to push two points away from one another. In a similar operation, a user can apply a force to the arms to cause an opening action to occur. When an opening action occurs, the arms move closer together from the starting or open state 532A allowing the engagement zone 526 to open. Upon releasing or reducing the force, the arms will return to the starting or open state 532A and the engagement zone 526 will return to its closed state.

FIG. 5B is a perspective view illustration of stent delivery system 500 engaging with a receiving vessel and donor vessel, through a modifiable stent, a coil stent, and an expansion tool in an expanded state. The stent delivery system 500, in at least one example, offers a user (medical professional) the ability to expand a vessel, such as, but not limited to a recipient vessel 518 and/or donor vessel 502, and allows the insertion of one or more stents, such as but not limited to a modifiable stent 504 and/or a coil stent 510. In some examples, the expansion tool 540 engages with the inner diameter or radius of a vessel (sometimes called the lumen) to expand the vessel to a size large enough to allow placement of one or more stents. As illustrated in FIG. 5A, the expansion tool 540 can be placed within the lumen of a vessel (illustrated as recipient vessel 518).

These stents can then engage with the vessel(s) to allow for proper placement. In at least one embodiment, the modifiable stent 504 is formed with a combination of modifiable member(s) 506 and non-modifiable member(s) 508, while in some examples, the modifiable stent 504 may be comprised of only modifiable member(s) 506 or non-modifiable member(s) 508. Additionally, in at least one example, the modifiable stent 504 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 504 to be anchored to a specific location or position within the vessel(s) or lumen.

Similarly, the coil stent 510, in at least one embodiment, is formed with coupling member(s) 516 (illustrated in FIG. 5A), and has a point set 512. In some examples, the coil stent 510 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 510 to be modified in a similar manner as the modifiable stent 504. While in other examples, the coil stent 510 may be formed from only modifiable member(s). The point set 512 of the coil stent 510 may include atraumatic point(s) 514A and/or traumatic point(s) 514B (illustrated in FIG. 5A), individually or in combination, to allow for engagement with one or more vessels, such as but not limited to the recipient vessel 518 and/or donor vessel 502.

In at least one embodiment, the modifiable stent 504 is co-axially located or concentric to the coil stent 510. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 504, in at least one example, is housed within the inner diameter of the coil stent 510. The concentric nature of the stent placements allow for the modifiable stent 504 to expand outwardly, to allow for proper fluid passage through the modifiable stent 504, while the coil stent 510 can engage with the vessels (illustrated as recipient vessel 518 and/or donor vessel 502) to prevent the movement of the modifiable stent 504 and/or the coil stent 510. In some examples, the lack of movement of the stents also allows for quicker healing when there vessels are placed in close proximity.

In at least one examples, the engagement zone 526 can have an internal void 530 (illustrated in FIG. 5A) that is defied by a set of engagement arms 528. The set of engagement arms 528 can have lengths that allow for engagement with various portions of one or both of the stents and/or a vessel described in the present disclosure. The set of engagement arms 528 can be elongated structures that are generally perpendicular to the arms 524A/524B. In some examples, the set of engagement arms 528 can be downwardly sloped to allow for additional engagement with vessel. In yet other examples, the set of engagement arms 528 may be upwardly sloped to allow for engagement with a vessel via external protrusions. In at least one embodiment, the set of engagement arms 528 have a set of engagement points 544 (not illustrated) that can be traumatic or atraumatic to allow for further engagement with a vessel. The engagement points 544 may be atraumatic points or traumatic points For simplicity, atraumatic points are those designed to not pierce or damage a lumen of a vessel, or other body part, while traumatic points may or may not pierce or otherwise damage, non-critically, a lumen of a vessel or other body part. The ability of the expansion tool 540 to engage with lumens of vessels or other body party may increase with the introduction of a flex point 548 that allows a portion of the engagement zone 526 to be flexible in relation to a second portion. For example, the second portion of the engagement zone 526 may be coupled to the extension arm(s) 542A/542B while the portion that is opposite the flex point 548 and second portion is free to move and can be biased to expand outwardly to allow for better engagement with a vessel, lumen, or body part.

In some examples, the expansion tool 540 may be called an expander tool because of its similarity in operation to an expander used in orthodontics to push two points away from one another. In a similar operation, a user can apply a force to the arms to cause an opening action to occur. When an opening action occurs, the arms move closer together from the starting or open state allowing the engagement zone 526 to open when the expansion tool is in an expanded state 532B. Upon releasing or reducing the force keeping the expansion tool in an expanded state 532B, the arms will return to the starting or open state, and the engagement zone 526 will return to its closed state.

FIG. 6A is a perspective cutaway view illustration of stent delivery system 600 having a combination tool and compression tool engaging with a coil stent and a modifiable stent. The combination tool 650 allows for delivery of one or more stents to one or more vessels with relative ease and simplicity. Traditionally, stent placement surgery can require many tedious hours and detailed surgery that can be risky to patients. The combination tool 650 allows a user or medical professional to insert one or more stents into a vessel and allow for a compression tool 620 to be included during the insert for quick use during a surgical procedure. In at least one example, the compression tool 620 can be utilized to insert the one or more stents into a second vessel after the combination tool 650 is utilized to insert the stent delivery system 600 into a first vessel.

The combination tool 650 can include a handle 652 for ease of gripping and controlling the insertion and/or placement of one or more stents utilizing the combination tool 650. The handle of the combination tool 650, can be connected to a first end 654, and a second end 656. In at least one example the first end 654 (in some examples, a distal end) may be distal from the second end 656 (in some examples, a proximal end). The second end 656 can be proximal to the user's control and/or hand during an operation, surgery, or procedure.

The first end 654, in at least one embodiment, can include a receiving aperture 658 that allows for one or more stents and/or stent covers or sheaths to pass through from the first end 654 to the second end 656 of the combination tool 650. In some examples the receiving aperture 658 can interact and/or engage with a container ring 662. The container ring 662 can be a ring or conduit that can be utilized to support one or more stents and/or stent covers or sheaths as they pass through and/or are contained within the first end 654 of the combination tool 650. In some examples, the container ring 662 may have an elongated section that surrounds the one or more stents. In at least one example, a containment void 664 may be present between the first end 654 and the second end 656. In some examples, the containment void 664 may be defined by a layer of material to assist in containing the one or more stents.

The second end 656, in at least one embodiment, can include a receiving void 660 that allows for the storage and/or containment of one or more stents, and/or covers or sheaths of the one or more stents. In at least one example, this allows for a modifiable stent 604 and/or coil stent 610 to be contained and prevented from expanding beyond the desired first state, or unmodified state. The second end 656 can define the receiving void 660 in a manner that allows it to prevent the expansion or modification of the one or more stents. In at least one example, the receiving void 660 is in communication with one or more receiving channels 668A and/or 668B. It would be understood that the receiving channels 668A/668B may be illustrated as two channels when viewed as a cross section view, but the two channels may be a single channel that is in a rounded or circular form. The receiving channels 668A/668B can surround a contact point 666 that allows for engagement and/or contact with the one or more stents, and/or sheaths or covers during a insertion procedure.

The compression tool 620, in at least one embodiment, can allow for the compression of a modifiable stent 604 and/or expansion of a coil stent 610. In at least one example, the compression tool 620 can have a set of engagement arms 628 with lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure. The set of engagement arms 628 are elongated structures, that may be downwardly or upwardly sloped to allow for additional engagement with one or more stents.

In at least one embodiment, the modifiable stent 604 is formed with a combination of modifiable member(s) and/or non-modifiable member(s). Additionally, in at least one example, the modifiable stent 604 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 604 to be anchored to a specific location or position within the vessel(s) or lumen. Similarly, the coil stent 610, in at least one embodiment, is formed with coupling member(s) 616 and has one or more point set(s) 612. In some examples, the coil stent 610 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 610 to be modified in a similar manner as the modifiable stent 604. While in other examples, the coil stent 610 may be formed from only modifiable member(s). The point set 612 of the coil stent 610 may include atraumatic point(s) 614A and/or traumatic point(s) 614B, individually or in combination, to allow for engagement with one or more vessels.

In at least one embodiment, the modifiable stent 604 is co-axially located or concentric to the coil stent 610. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 604, in at least one example, is housed within the inner diameter of the coil stent 610. The concentric nature of the stent placements allows for the modifiable stent 604 to expand outwardly, to allow for proper fluid passage through the modifiable stent 604, while the coil stent 610 can engage with the vessels to prevent the movement of the modifiable stent 604 and/or the coil stent 610. In some examples, the lack of movement of the stents also allows for quicker healing when there vessels are placed in close proximity.

FIG. 6B is a perspective cutaway view illustration of stent delivery system 600 having a combination tool and compression tool engaging with a coil stent and a modifiable stent. The combination tool 650 allows for delivery of one or more stents to one or more vessels with relative ease and simplicity. Traditionally, stent placement surgery can require many tedious hours and detailed surgery that can be risky to patients. The combination tool 650 allows a user or medical professional to insert one or more stents into a vessel and allows for a compression tool 620 to be included during the insert for quick use during a surgical procedure. In at least one example, the compression tool 620 can be utilized to insert the one or more stents into a second vessel after the combination tool 650 is utilized to insert the stent delivery system 600 into a first vessel.

The combination tool 650 can include a handle 652 for ease of gripping and controlling the insertion and/or placement of one or more stents utilizing the combination tool 650. The handle of the combination tool 650 can be connected to a first end 654 and a second end 656. In at least one example the first end 654 (in some examples, a distal end) may be distal from the second end 656 (in some examples, a proximal end). The second end 656 can be proximal to the user's control and/or hand during an operation, surgery, or procedure.

The first end 654, in at least one embodiment, can interact and/or engage with a container ring 662. The container ring 662 can be a ring or conduit that can be utilized to support one or more stents and/or stent covers or sheaths as they pass through and/or contained within the first end 654 of the combination tool 650. In some examples, the container ring 662 may have an elongated section that surrounds the one or more stents.

The compression tool 620, in at least one embodiment, can allow for the compression of a modifiable stent (not illustrated) and/or expansion of a coil stent 610. The engagement section 626 of the compression tool, in at least one embodiment, can be connected by arms 624A and/or 624B. The arms 624A/624B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement zone 626. The engagement zone 626, can have an internal void 630 (illustrated in FIG. 6B) that is defined by a set of engagement arms 628. The set of engagement arms 628 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure.

In at least one example, the set of engagement arms 628 are elongated structures that are generally perpendicular to the arms 624A/624B. The set of engagement arms 628 are elongated structures, that may be downwardly or upwardly sloped to allow for additional engagement with one or more stents. In some examples, the set of engagement arms 628 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). In yet other examples, the set of engagement arms 628 may be upwardly sloped to allow for engagement with one or more stents with external protrusions. In at least one example, the set of engagement arms 628 can be engaged with the first end 654 and/or receiving aperture 658 to allow or storage during the procedure and/or insertion of the one or more stents. The engagement zone 626, can have an internal void 630 (illustrated in FIG. 6B) that is defined by a set of engagement arms 628.

In at least one embodiment, the coil stent 610, is formed with coupling member(s) 616 (illustrated in FIG. 6A) and has one or more point set(s) 612 (illustrated in FIG. 6A). In some examples, the coil stent 610 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 610 to be modified in a similar manner as the modifiable stent. While in other examples, the coil stent 610 may be formed from only modifiable member(s). The point set 612 of the coil stent 610 may include atraumatic point(s) 614A and/or traumatic point(s) 614B (illustrated in FIG. 6A), individually or in combination, to allow for engagement with one or more vessels.

In at least one embodiment, the modifiable stent 604 is co-axially located or concentric to the coil stent 610. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 604, in at least one example, is housed within the inner diameter of the coil stent 610. The concentric nature of the stent placements allows for the modifiable stent 604 to expand outwardly, to allow for proper fluid passage through the modifiable stent 604, while the coil stent 610 can engage with the vessels to prevent the movement of the modifiable stent 604 and/or the coil stent 610. In some examples, the lack of movement of the stents also allows for quicker healing when their vessels are placed in close proximity.

The modifiable stent (not illustrated) may be separated from the coil stent 610 and/or compression tool 620 by a sheath or cover 670. In at least one example, the sheath or cover 670 may include various tears or perforations that allow for it to be removed easier from the one or more stents. In other examples, the sheath or cover 670 may be formed of a material that can define a cover void 672 that can receive and/or surround one or more stents.

FIG. 7A is a perspective view illustration of a stent delivery system 700 having a donor vessel 702, a modifiable stent 704, a coil stent 710, and a compression tool 720 in an open state 732A. The stent delivery system 700, in at least one example, provides a user (a medical professional) with the ability to compress one or more stents, such as but not limited to the modifiable stent 704 and/or coil stent 710, for easy of entry and/or placement within one or more vessels such as, but not limited to the donor vessel 702 and/or a recipient vessel (not illustrated). In some examples, the compression tool 720 engages with one or both of the stents (illustrated as modifiable stent 704 and/or coil stent 710), to allow for the ease of insertion into one or more vessels.

In at least one embodiment, the modifiable stent 704 is formed with a combination of modifiable member(s) 706 and non-modifiable member(s) 708, while in some examples, the modifiable stent 704 may be comprised of only modifiable member(s) 706 or non-modifiable member(s) 708. Additionally, in at least one example, the modifiable stent 704 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 704 to be anchored to a specific location or position within the vessel(s) or lumen.

Similarly, the coil stent 710, in at least one embodiment, is formed with coupling member(s) 716, and has a point set 712. In some examples, the coil stent 710 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 710 to be modified in a similar manner as the modifiable stent 704, while in other examples, the coil stent 710 may be formed from only modifiable member(s). The point set 712 of the coil stent 710 may include atraumatic point(s) 714A and/or traumatic point(s) 714B, individually or in combination, to allow for engagement with one or more vessels, such as but not limited to the recipient vessel (not illustrated) and/or donor vessel 702.

In at least one embodiment, the modifiable stent 704 is co-axially located or concentric to the coil stent 710. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 704, in at least one example, is housed within the inner diameter of the coil stent 710. The concentric nature of the stent placements allows for the modifiable stent 704 to expand outwardly, to allow for proper fluid passage through the modifiable stent 704, while the coil stent 710 can engage with the vessels (illustrated as recipient vessel (not illustrated) and/or donor vessel 702) to prevent the movement of the modifiable stent 704 and/or the coil stent 710. In some examples, the lack of movement of the stents also allows for quicker healing when their vessels are placed in close proximity.

The engagement section 726, in at least one embodiment, can be connected by arms 724A and/or 724B. The arms 724A/724B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement zone 726. The engagement zone 726, can have an internal void 730 that is defined by a set of engagement arms 728. The set of engagement arms 728 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure. In at least one example, the set of engagement arms 728 may also have one or more coupling points 774. The coupling points 774 may allow for the compression tool 720 to interact and/or engage with vessels in a manner that avoids the vessel slipping or sliding in a direction away from the one or more stents.

In at least one example, the set of engagement arms 728 are elongated structures that are generally perpendicular to the arms 724A/724B. In some examples, the set of engagement arms 728 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). In yet other examples, the set of engagement arms 728 may be upwardly sloped to allow for engagement with one or more stents with external protrusions. In at least one embodiment, the engagement arm(s) 728 and a tapered end can allow for a user to more easily engage and/or place the stents within a vessel, such as but not limited to the recipient vessel or donor vessel 702.

In some examples, the compression tool 720 may be called a tweezer tool because of its similarity in operation to a tweezer. In a similar operation, a user can apply a force to the arms to cause a closing action to occur. When a closing action occurs, the arms move closer together from the starting or open state 732A. Upon releasing or reducing the force, the arms will return to the starting or open state 732A.

FIG. 7B is a perspective view illustration of a stent delivery system 700 having a donor vessel 702, a modifiable stent 704, a coil stent 710, and a compression tool 720 in an open state 732A. The stent delivery system 700, in at least one example, provides a user (a medical professional) with the ability to compress one or more stents, such as but not limited to the modifiable stent 704 and/or coil stent 710, for ease of entry and/or placement within one or more vessels, such as, but not limited to the donor vessel 702 and/or a recipient vessel (not illustrated). In some examples, the compression tool 720 engages with one or both of the stents (illustrated as modifiable stent 704 and/or coil stent 710), to allow for the ease of insertion into one or more vessels.

In at least one embodiment, the modifiable stent 704 is formed with a combination of modifiable member(s) 706 and non-modifiable member(s) 708 while in some examples, the modifiable stent 704 may be comprised of only modifiable member(s) 706 or non-modifiable member(s) 708. Additionally, in at least one example, the modifiable stent 704 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 704 to be anchored to a specific location or position within the vessel(s) or lumen. In some examples, the modifiable stent 704 may have one or more (a set of) receiving points 776 that may receive one or more anchor points of the coil stent 710. This may allow for the positioning of the stent in a more reliable manner.

Similarly, the coil stent 710, in at least one embodiment, is formed with coupling member(s) 716, and has a point set 712. In some examples, the coil stent 710 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 710 to be modified in a similar manner as the modifiable stent 704, while in other examples, the coil stent 710 may be formed from only modifiable member(s). The point set 712 of the coil stent 710 may include atraumatic point(s) 714A and/or traumatic point(s) 714B (illustrated in FIG. 7A), individually or in combination, to allow for engagement with one or more vessels, such as but not limited to the a recipient vessel (not illustrated) and/or donor vessel 702.

In at least one embodiment, the modifiable stent 704 is co-axially located or concentric to the coil stent 710. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 704, in at least one example, is housed within the inner diameter of the coil stent 710. The concentric nature of the stent placements allows for the modifiable stent 704 to expand outwardly, to allow for proper fluid passage through the modifiable stent 704, while the coil stent 710 can engage with the vessels (illustrated as recipient vessel (not illustrated) and/or donor vessel 702) to prevent the movement of the modifiable stent 704 and/or the coil stent 710. In some examples, the lack of movement of the stents also allows for quicker healing when their vessels are placed in close proximity.

The engagement section 726, in at least one embodiment, can be connected by arms 724A and/or 724B. The arms 724A/724B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement zone 726. The engagement zone 726, can have an internal void 730 that is defined by a set of engagement arms 728. The set of engagement arms 728 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure. In at least one example, the set of engagement arms 728 may also have one or more coupling points 774. The coupling points 774 may allow for the compression tool 720 to interact and/or engage with vessels in a manner that avoids the vessel slipping or sliding in a direction away from the one or more stents.

In at least one example, the set of engagement arms 728 are elongated structures that are generally perpendicular to the arms 724A/724B. In some examples, the set of engagement arms 728 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). In yet other examples, the set of engagement arms 728 may be upwardly sloped to allow for engagement with one or more stents with external protrusions. In at least one embodiment, the engagement arm(s) 728 and a tapered end can allow for a user to more easily engage and/or place the stents within a vessel, such as but not limited to the recipient vessel or donor vessel 702.

In some examples, the compression tool 720 may be called a tweezer tool because of its similarity in operation to a tweezer. In a similar operation, a user can apply a force to the arms to cause a closing action 732B to occur. When a closing action 732B occurs, the arms move closer together from the starting or open state illustrated in FIG. 7A. Upon releasing or reducing the force, the arms will return to the starting or open state.

FIG. 7C is a perspective view illustration of a stent delivery system 700 having a recipient vessel 718, a donor vessel 702, a modifiable stent 704, a coil stent 710, and a compression tool 720 in an open state 732C. The stent delivery system 700, in at least one example, provides a user (a medical professional) with the ability to compress one or more stents, such as but not limited to the modifiable stent 704 and/or coil stent 710, for ease of entry and/or placement within one or more vessels such as, but not limited to the donor vessel 702 and/or a recipient vessel 718. In some examples, the compression tool 720 engages with one or both of the stents (illustrated as modifiable stent 704 and/or coil stent 710), to allow for the ease of insertion into one or more vessels.

In at least one embodiment, the modifiable stent 704 is formed with a combination of modifiable member(s) 706 and non-modifiable member(s) 708, while in some examples, the modifiable stent 704 may be comprised of only modifiable member(s) 706 or non-modifiable member(s) 708. Additionally, in at least one example, the modifiable stent 704 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 704 to be anchored to a specific location or position within the vessel(s) or lumen.

Similarly, the coil stent 710, in at least one embodiment, is formed with coupling member(s) 716, and has a point set 712. In some examples, the coil stent 710 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 710 to be modified in a similar manner as the modifiable stent 704 while in other examples, the coil stent 710 may be formed from only modifiable member(s). The point set 712 of the coil stent 710 may include atraumatic point(s) 714A and/or traumatic point(s) 714B (illustrated in FIG. 7A), individually or in combination, to allow for engagement with one or more vessels, such as but not limited to the a recipient vessel 718 and/or donor vessel 702.

In at least one embodiment, the modifiable stent 704 is co-axially located or concentric to the coil stent 710. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 704, in at least one example, is housed within the inner diameter of the coil stent 710. The concentric nature of the stent placements allows for the modifiable stent 704 to expand outwardly, to allow for proper fluid passage through the modifiable stent 704, while the coil stent 710 can engage with the vessels (illustrated as recipient vessel 718 and/or donor vessel 702) to prevent the movement of the modifiable stent 704 and/or the coil stent 710. In some examples, the lack of movement of the stents also allows for quicker healing when their vessels are placed in close proximity.

The engagement section 726, in at least one embodiment, can be connected by arms 724A and/or 724B illustrated in FIG. 7A. The arms 724A/724B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement zone 726. The engagement zone 726, can have an internal void 730 that is defined by a set of engagement arms 728. The set of engagement arms 728 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure. In at least one example, the set of engagement arms 728 may also have one or more coupling points 774 (illustrated in FIG. 7A). The coupling points 774 may allow for the compression tool 720 to interact and/or engage with vessels in a manner that avoids the vessel slipping or sliding in a direction away from the one or more stents.

In at least one example, the set of engagement arms 728 are elongated structures that are generally perpendicular to the arms 724A/724B. In some examples, the set of engagement arms 728 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). In yet other examples, the set of engagement arms 728 may be upwardly sloped to allow for engagement with one or more stents with external protrusions. In at least one embodiment, the engagement arm(s) 728 and a tapered end can allow for a user to more easily engage and/or place the stents within a vessel, such as but not limited to the recipient vessel or donor vessel 702.

In some examples, the compression tool 720 may be called a tweezer tool because of its similarity in operation to a tweezer. In a similar operation, a user can apply a force to the arms to cause a closing action 732C to occur. When a closing action 732C occurs, the arms move closer together from the starting or open state illustrated in FIG. 7A. Upon releasing or reducing the force, the arms will return to the starting or open state.

FIG. 7D is a perspective view illustration of a stent delivery system 700 having a recipient vessel 718, a donor vessel 702, a modifiable stent 704, a coil stent 710, and a compression tool 720 in an closed state 732D. The stent delivery system 700, in at least one example, provides a user (a medical professional) with the ability to compress one or more stents, such as but not limited to the modifiable stent 704 and/or coil stent 710, for easy of entry and/or placement within one or more vessels such as, but not limited to the donor vessel 702 and/or a recipient vessel 718. In some examples, the compression tool 720 engages with one or both of the stents (illustrated as modifiable stent 704 and/or coil stent 710), to allow for the ease of insertion into one or more vessels.

In at least one embodiment, the modifiable stent 704 is formed with a combination of modifiable member(s) 706 and non-modifiable member(s) 708, while in some examples, the modifiable stent 704 may be comprised of only modifiable member(s) 706 or non-modifiable member(s) 708. Additionally, in at least one example, the modifiable stent 704 may also have additional traumatic or atraumatic anchor points (not illustrated) that allow for the modifiable stent 704 to be anchored to a specific location or position within the vessel(s) or lumen.

Similarly, the coil stent 710, in at least one embodiment, is formed with coupling member(s) 716, and has a point set 712 (illustrated in FIG. 7A). In some examples, the coil stent 710 may also include modifiable member(s) (not illustrated) that would allow for the coil stent 710 to be modified in a similar manner as the modifiable stent 704. While in other examples, the coil stent 710 may be formed from only modifiable member(s). The point set 712 of the coil stent 710 may include atraumatic point(s) 714A and/or traumatic point(s) 714B (illustrated in FIG. 7A), individually or in combination, to allow for engagement with one or more vessels, such as but not limited to the a recipient vessel 718 and/or donor vessel 702.

In at least one embodiment, the modifiable stent 704 is co-axially located or concentric to the coil stent 710. For clarity, in some examples, there can be a covering or sheath between the stents and/or vessels. The modifiable stent 704, in at least one example, is housed within the inner diameter of the coil stent 710. The concentric nature of the stent placements allow for the modifiable stent 704 to expand outwardly, to allow for proper fluid passage through the modifiable stent 704, while the coil stent 710 can engage with the vessels (illustrated as recipient vessel 718 and/or donor vessel 702) to prevent the movement of the modifiable stent 704 and/or the coil stent 710. In some examples, the lack of movement of the stents also allows for quicker healing when there vessels are placed in close proximity.

The engagement section 726, in at least one embodiment, can be connected by arms 724A and/or 724B. The arms 724A/724B as seen in FIG. 7A, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress and/or close the engagement zone 726. The engagement zone 726, can have an internal void 730 (illustrated in FIG. 7C) that is defied by a set of engagement arms 728. The set of engagement arms 728 can have lengths that allow for engagement with various portions of one or both of the stents described in the present disclosure. In at least one example, the set of engagement arms 728 may also have one or more coupling points 774 (illustrated in FIG. 7A). The coupling points 774 may allow for the compression tool 720 to interact and/or engage with vessels in a manner that avoids the vessel slipping or sliding in a direction away from the one or more stents.

In at least one example, the set of engagement arms 728 are elongated structures that are generally perpendicular to the arms 724A/724B. In some examples, the set of engagement arms 728 can be downwardly sloped to allow for additional engagement with one or more stents (not illustrated). In yet other examples, the set of engagement arms 728 may be upwardly sloped to allow for engagement with one or more stents with external protrusions. In at least one embodiment, the engagement arm(s) 728 and a tapered end can allow for a user to more easily engage and/or place the stents within a vessel, such as but not limited to the recipient vessel or donor vessel 702.

In some examples, the compression tool 720 may be called a tweezer tool because of its similarity in operation to a tweezer. In a similar operation, a user can apply a force to the arms to cause a closing action to occur. When a closing action occurs, the arms move closer together from the starting or open state 732D. Upon releasing or reducing the force, the arms will return to the starting or open state 732D.

FIG. 8A is a perspective view illustration of stent delivery system 800 having a delivery tool 820 and a coil stent 810. The delivery tool 820 allows for a vessel (not illustrated) to be guided into a position that the coil stent 810 can be delivered. The delivery tool 820 has a first end or engagement section that is opposite and distal from an inflection point. The inflection point allows for the spring and/or resistive force that allows the delivery tool 820 to remain in a neutral state when not compressed by a user or external force (not illustrated).

The engagement section and the inflection point, in at least one embodiment, can be connected by arms 882A and/or 882B. The arms 882A/882B, in at least one example, may be of a length that allows for a reasonable force to be applied by a user to compress the arms 882A/882B and/or open the engagement zone. Transfer arms 884A and/or 884B can allow a for the transfer of the compression or reasonable force applied by a user to extension arms 886A and/or 886B. The transfer arms 884A/884B may be of a length that allows for the closing of the engagement zone when the delivery tool 820 is in a neutral state and are generally perpendicular to the arms 882A/882B and/or extension arms 886A/886B. In some examples, engagement zone may also be referenced as an engagement section. The extension arms 886A/886B can act as an extension of the arms 882A/882B but are in opposite planes in order to allow for the expansion of the delivery tool 880. For example, arm 882A corresponds to the extension arm 886B, and arm 882B corresponds to extension arm 886A. This cross over is possible because of the transfer arms 884A/884B.

In some examples, the delivery tool 820 may be called an expander tool because of its similarity in operation to an expander used in orthodontics to push two points away from one another. In a similar operation, a user can apply a force to the arms to cause an opening action to occur. When an opening action occurs, the arms move closer together from the starting or open state allowing the engagement zone to open. Upon releasing or reducing the force, the arms will return to the starting or open state and the engagement zone will return to it's closed state.

The engagement zone, in at least one embodiment, may include a set of guides 890 that provide direction for the coupling of the delivery tool 820 to a vessel (not illustrated). The set of guides 890, in at least one example, can include engagement points 892 that can engage with the vessel to prevent it from moving during the delivery and/or insertion of the stent 810. The delivery tool 820 can also include a transfer guide 894 that allows for guiding the stent 810 into position within a vessel. The transfer guide 894 can include a portion that goes within the stent 810 and a portion that surrounds the outside of the stent 810. In at least one example, there can be a transfer guide engagement zone 891 (see FIG. 8B) between the outer portion of the transfer guide 894 and the stent 810. In at least one embodiment, the transfer guide 894 is removable with the stent 810 from the engagement zone of the delivery tool 820.

FIG. 8B is a perspective view illustration of a delivery tool 820 and a coil stent 810. The delivery tool 820 allows for a vessel (not illustrated) to be guided into a position that the coil stent 810 can be delivered. The delivery tool 820 has a first end or engagement section that is opposite and distal from an inflection point. The inflection point allows for the spring and/or resistive force that allows the delivery tool 820 to remain in a neutral state when not compressed by a user or external force (not illustrated).

Transfer arms can allow a for the transfer of the compression or reasonable force applied by a user to extension arms 886A and/or 886B. In some examples, engagement zone may also be referenced as an engagement section. The extension arms 886A/886B can act as an extension of the arms but are in opposite planes in order to allow for the expansion of the delivery tool 820.

In some examples, the delivery tool 820 may be called an expander tool because of its similarity in operation to an expander used in orthodontics to push two points away from one another. In a similar operation, a user can apply a force to the arms to cause an opening action to occur. When an opening action occurs, the arms move closer together from the starting or open state allowing the engagement zone to open. Upon releasing or reducing the force, the arms will return to the starting or open state and the engagement zone will return to it's closed state.

The engagement zone, in at least one embodiment, may include a set of guides 890 that provide direction for the coupling of the delivery tool 820 to a vessel (not illustrated). The set of guides 890, in at least one example, can include engagement points 892 that can engage with the vessel to prevent it from moving during the delivery and/or insertion of the stent 810. The delivery tool 820 can also include a transfer guide 894 that allows for guiding the stent 810 into position within a vessel. The transfer guide 894 can include a portion that goes within the stent 810 and a portion that surrounds the outside of the stent 810. In at least one example, there can be a transfer guide engagement zone 891 between the outer portion of the transfer guide 894 and the stent 810. In at least one embodiment, the transfer guide 894 is removable with the stent 810 from the engagement zone of the delivery tool 820.

The transfer guide 894, in at least one example, may also include engagement neck 893 that can prevent the expansion of the stent 810, and/or engage with a vessel to allow for ease of insertion. An internal void 896 of the transfer guide 894 can be present and allow for additional stents and/or tools to be inserted into the vessel. For example, a first stent may be inserted while the coil stent 810 is wrapped around it as a specific point. Alternatively, the coil stent 810 may be delivered onto a first vessel that may or may not have a stent within in it, while a second vessel is engage with the guides allowing the coil stent 810 to engage the first and second vessels for potential healing together. As part of this example, a transfer guide notch 898 may be utilized to push and/or guide the stent 810 away from the transfer guide 894 and/or delivery tool 820.

FIG. 9A is a perspective view illustration of a dual stent delivery tool 901 (in some examples a stent delivery tool 901) that can be utilized as an apparatus and system, and as part of a method of using the dual stents. In at least one embodiment, the dual stent delivery tool 901 may be utilized to place two stents with a single button press, allowing for the first portion of an amitosis surgery to be completed in just a few seconds, rather than the current methods which can take up to ten to twenty minutes per vessel. In some examples, the dual stent delivery tool 901 be included as part of a set of delivery tools or in sterilized blister packs that can be opened and utilized in rapid succession during intensive surgery.

The dual stent delivery tool 901 can have a main body 903 for housing the internal workings of the stent delivery tool 901, and in at least one example, partially housing and/or containing one or more stents. In at least one embodiment, the main body 903 can be cylindrical, with a first end having a back stop 905, and a second end opposing the first end, the second end having an opening to receive the one or more stents. In some examples, the main body 903 may have additional openings, apertures, or other structures that pass through or along portions of the main body 903. The back stop 905 may be threaded, friction fit, or otherwise coupled to the main body 903 in a manner that prevents it from being removed from the main body 903 without additional outside forces.

A firing tab or button 907 may be utilized by a user or medical professional to activate the mechanisms to transfer one or both of the stents. It would be understood, that while one button is illustrated, in at least one example, two or more buttons may be utilized to trigger the transfer and/or insertion of one or more stents, and/or other activities related to these and similar procedures. In some examples of the dual stent delivery tool 901, there may be additional firing tab(s) or button(s) 907 to allow for vessels to be engaged or disengaged, along with the engagement or disengagement of one or more stents.

When the firing tab 907 is pressed, a lead in 909, in some examples called an olive tip lead in, can extend or retract based on the design of the dual stent delivery tool 901. The lead in 909 can be shaped like a rounded bullet with a tapered front end, coupled to a cylindrical section, and a tapered rear section that coupled to a plunger and/or rod. While the olive shape is illustrated, other shapes may be utilized without departing from the spirit of the present disclosure.

In at least one embodiment, the lead in 909 can engage and/or interact with an inner stent 911. In at least one example, the inner stent 911 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 911 may also have one or more anchor points that when engaged can allow the inner stent 911 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 913 can compress and/or prevent the modification of the inner stent 911 prior to the removal of the inner stent covering 913. In some examples, the inner stent covering 913 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. Similarly, the outer stent 915 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 915 may also have one or more anchor points that when engaged can allow the inner stent 915 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 917 can compress and/or prevent the modification of the inner stent 915 prior to the removal of the inner stent covering 917. In some examples, the inner stent covering 917 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. The inner stent 911 can be co-axially related to the outer stent 915 such that the inner stent 911 is within the inner radius or diameter of the outer stent 915.

FIG. 9B is a perspective view illustration of a dual stent delivery tool 901 in a zoomed view of the front section of the dual stent delivery tool 901. In at least one embodiment, the dual stent delivery tool 901 may be utilized to place two stents with a single button press, allowing for the first portion of an amitosis surgery to be completed in just a few seconds, rather than the current methods which can take up to ten to twenty minutes per vessel. In some examples, the dual stent delivery tool 901 can be included as part of a set of delivery tools or in sterilized blister packs that can be opened and utilized in rapid succession during intensive surgery.

The dual stent delivery tool 901 can have a main body 903 for housing the internal workings of the stent delivery tool 901, and in at least one example, partially housing and/or containing one or more stents. In at least one embodiment, the main body 903 can be cylindrical, with a first end having a back stop 905 (see FIG. 9A), and a second end opposing the first end, and the second end having an opening to receive the one or more stents. In some examples, the main body 903 may have additional openings, apertures, or other structures that pass through or along portions of the main body 903. The back stop 905 may be threaded, friction fit, or otherwise coupled to the main body 903 in a manner that prevents it from being removed from the main body 903 without additional outside forces.

A firing tab or button 907 (see FIG. 9A) may be utilized by a user or medical professional to activate the mechanisms to transfer one or both of the stents. It would be understood, that while one button is illustrated, in at least one example two or more buttons may be utilized to trigger the transfer and/or insertion of one or more stents, and/or other activities related to these and similar procedures. In some examples of the dual stent delivery tool 901, there may be additional firing tab(s) or button(s) 907 to allow for vessels to be engaged or disengaged, along with the engagement or disengagement of one or more stents.

When the firing tab 907 is pressed, a lead in 909, in some examples called an olive tip lead in, can extend or retract based on the design of the dual stent delivery tool 901. The lead in 909 can be shaped like a rounded bullet with a tapered front end, coupled to a cylindrical section, and a tapered rear section that coupled to a plunger and/or rod. While the olive shape is illustrated, other shapes may be utilized without departing from the spirit of the present disclosure.

In at least one embodiment, the lead in 909 can engage and/or interact with an inner stent 911. In at least one example, the inner stent 911 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 911 may also have one or more anchor points that when engaged can allow the inner stent 911 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 913 can compress and/or prevent the modification of the inner stent 911 prior to the removal of the inner stent covering 913. In some examples, the inner stent covering 913 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. Similarly, the outer stent 915 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 915 may also have one or more anchor points that when engaged can allow the inner stent 915 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 917 can compress and/or prevent the modification of the inner stent 915 prior to the removal of the inner stent covering 917. In some examples, the inner stent covering 917 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. The inner stent 911 can be co-axially related to the outer stent 915 such that the inner stent 911 is within the inner radius or diameter of the outer stent 915.

The main body 903 can include a body aperture 919 that allows for access to the internal portions of the main body 903. In at least one example, the body aperture 919 is sized and/or configured to allow for the passage and/or storage of one or both stents, a plunger or rod, a firing mechanism (not illustrated), and/or the lead in 909.

FIG. 9C is a cross-sectional view illustration of a dual stent delivery tool 901. In at least one embodiment, the dual stent delivery tool 901 may be utilized to place two stents with a single button press, allowing for the first portion of an amitosis surgery to be completed in just a few seconds, rather than the current methods which can take up to ten to twenty minutes per vessel. In some examples, the dual stent delivery tool 901 be included as part of a set of delivery tools or in sterilized blister packs that can be opened and utilized in rapid succession during intensive surgery.

The dual stent delivery tool 901 can have a main body 903 for housing the internal workings of the stent delivery tool 901, and in at least one example, partially housing and/or containing one or more stents. In at least one embodiment, the main body 903 can be cylindrical, with a first end having a back stop 905, and a second end opposing the first end, and the second end having an opening to receive the one or more stents. In some examples, the main body 903 may have additional openings, apertures, or other structures that pass through or along portions of the main body 903. The back stop 905 may be threaded, friction fit, or otherwise coupled to the main body 903 in a manner that prevents it from being removed from the main body 903 without additional outside forces.

A firing tab or button 907 may be utilized by a user or medical professional to activate the mechanisms to transfer one or both of the stents. It would be understood that while one button is illustrated, in at least one example two or more buttons may be utilized to trigger the transfer and/or insertion of one or more stents, and/or other activities related to these and similar procedures. In some examples of the dual stent delivery tool 901, there may be additional firing tab(s) or button(s) 907 to allow for vessels to be engaged or disengaged, along with the engagement or disengagement of one or more stents.

When the firing tab 907 is pressed, a lead in 909, in some examples called an olive tip lead in can extend or retract based on the design of the dual stent delivery tool 901. The lead in 909 can be shaped like a rounded bullet with a tapered front end, coupled to a cylindrical section, and a tapered rear section that coupled to a plunger and/or rod. While the olive shape is illustrated, other shapes may be utilized without departing from the spirit of the present disclosure.

In at least one embodiment, the lead in 909 can engage and/or interact with an inner stent 911. In at least one example, the inner stent 911 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 911 may also have one or more anchor points that, when engaged, can allow the inner stent 911 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 913 can compress and/or prevent the modification of the inner stent 911 prior to the removal of the inner stent covering 913. In some examples, the inner stent covering 913 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. Similarly, the outer stent 915 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 915 may also have one or more anchor points that when engaged can allow the inner stent 915 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 917 can compress and/or prevent the modification of the inner stent 915 prior to the removal of the inner stent covering 917. In some examples, the inner stent covering 917 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. The inner stent 911 can be co-axially related to the outer stent 915 such that the inner stent 911 is within the inner radius or diameter of the outer stent 915.

The main body 903 can include a body aperture 919 that allows for access to the internal portions of the main body 903. In at least one example, the body aperture 919 is sized and/or configured to allow for the passage and/or storage of one or both stents, a plunger or rod, a firing mechanism (not illustrated), and/or the lead in 909.

The cover carrier 921, in some examples a sheath carrier, can allow for a coupling to the one or more sheaths or coverings for the stents of the present disclosure. In at least one example, the covers or sheaths are coupled to the cover carrier 921 in a manner that when the firing button or tab 907 is pressed, it releases the cover carrier 921, causing it to move and thereby moving the stent covers or sheaths as well. The cover carrier 921 may also have a cover carrier engagement aperture 923 that allows portions of the firing tab or button 907 to pass through and/or interact with the cover carrier 921. In some examples, the cover carrier engagement aperture 923 may be formed in such a way that it must be positioned correctly in order to engage or interact with portion of the firing tab or button 907, while in other examples, the cover carrier engagement aperture 923 may have a consistent configuration around the entire perimeter of the cover carrier 921. The cover carrier 921, in at least one embodiment, can have a cover carrier retention zone 925. The cover carrier retention zone 925 can be an area to receive a spring or other retention mechanism. In at least one embodiment, the cover carrier retention zone 925 may also be able to engage with a pushing or acceleration mechanism that can push the cover carrier 921 away from the back stop 905. The cover carrier retention zone 925, and/or the cover carrier engagement aperture 923 can surround and/or device a cover carrier pass through void 927 that allows a rod or plunger to pass through the cover carrier 921.

The lead in 909 can be coupled to a lead in shaft 929. The lead in shaft 929 can be a rod or plunger that passes through the body aperture 919. In some examples, it can couple with a plunger rod 931. In at least one example the plunger rod 931 surrounds the lead in shaft 929 to provide additional support. In other examples, the plunger rod 931 can be an extension of the lead in shaft 929.

In at least on embodiment, a retention mechanism 933 can be utilized to engage the cover carrier 921 backwards towards the back stop 905 or forwards towards the body aperture 919. In at least one example, the retention mechanism 933 is a spring, while in other examples, other forms of mechanism that can impart kinetic energy may be utilized. When the firing tab or button 907 is engaged by the user and passes a portion of the firing tab or button through the main body firing tab aperture 943, the kinetic energy stored in the retention mechanism 933 can be released.

The retention mechanism 933 can be coupled between the cover carrier retention zone 925 and the back stop retention zone 945. The back stop retention zone 945 can be an area to receive a spring or other retention mechanism. In at least one embodiment, the back stop retention zone 945 may also be able to engage with a pushing or acceleration mechanism that can push the cover carrier 921 away from the back stop 905. The lead in 909 interaction depth with a vessel (not illustrated) can be adjusted with a depth adjustment 935. In at least one example, the depth adjustment 935 interacts with the back stop 905 though a threaded connection, while other connections that allow for changes of positioning between two elements would not depart from the spirit of the present disclosure. The threaded connection may be illustrated by a depth adjustment engagement surface 939 along the outer perimeter of the depth adjustment 935, and the inner perimeter of the back stop 905.

The lead in shaft 929, and/or plunger rod 931 can pass through and/or engage with a back stop aperture 937 defined by the back stop 905, and/or the depth adjustment aperture 941 defined by the depth adjustment 935. In at least one example, the back stop aperture 937 can allow for the passage of the lead in shaft 929 and the plunger rod 931 while the depth adjustment aperture 941 only allows for the passage of the lead in shaft 929. Further to this example, the depth of the lead in 909 engagement with a vessel can be controlled by the amount of the shaft and/or rod that is allowed to pass through them.

FIG. 10 is an exploded view illustration of a dual stent delivery tool 1001. In at least one embodiment, the dual stent delivery tool 1001 may be utilized to place two stents with a single button press, allowing for the first portion of an amitosis surgery to be completed in just a few seconds, rather than the current methods which can take up to ten to twenty minutes per vessel. In some examples, the dual stent delivery tool 1001 be included as part of a set of delivery tools or in sterilized blister packs that can be opened and utilized in rapid succession during intensive surgery.

The dual stent delivery tool 1001 can have a main body 1003 for housing the internal workings of the stent delivery tool 1001, and in at least one example, partially housing and/or containing one or more stents. In at least one embodiment, the main body 1003 can be cylindrical, with a first end having a back stop 1005, and a second end opposing the first end, and the second end having an opening to receive the one or more stents. In some examples, the main body 1003 may have additional openings, apertures, or other structures that pass through or along portions of the main body 1003. The back stop 1005 may be threaded, friction fit, or otherwise coupled to the main body 1003 in a manner that prevents it from being removed from the main body 1003 without additional outside forces. The main body 1003 may house all of the components with the exception of portions of the lead in 1009 and/or lead in shaft 1029, firing tab or button 1007, the back stop 1005, and/or depth adjustment 1035.

A firing tab or button 1007 may be utilized by a user or medical professional to activate the mechanisms to transfer one or both of the stents. It would be understood, that while one button is illustrated, in at least one example, two or more buttons may be utilized to trigger the transfer and/or insertion of one or more stents, and/or other activities related to these and similar procedures. The firing tab or button 1007 may include firing tab or button engagement extensions 1047 that can engage with the cover carrier 1021. In at least one example, the firing tab or button 1007, when pressed, the firing tab extension 1047 passes through the cover carrier engagement aperture releasing the cover carrier 1021 and causing it to move. In some examples of the dual stent delivery tool 1001, there may be additional firing tab(s) or button(s) 1007 to allow for vessels to be engaged or disengaged, along with the engagement or disengagement of one or more stents.

When the firing tab 1007 is pressed, a lead in 1009, in some examples called an olive tip lead in, can extend or retract based on the design of the dual stent delivery tool 1001. The lead in 1009 can be shaped like a rounded bullet with a tapered front end, coupled to a cylindrical section, and a tapered rear section that coupled to a plunger and/or rod. While the olive shape is illustrated, other shapes may be utilized without departing from the spirit of the present disclosure.

In at least one embodiment, the lead in 1009 can engage and/or interact with an inner stent 1011. In at least one example, the inner stent 1011 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 1011 may also have one or more anchor points that when engaged can allow the inner stent 1011 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 1013 can compress and/or prevent the modification of the inner stent 1011 prior to the removal of the inner stent covering 1013. In some examples, the inner stent covering 1013 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. Similarly, the outer stent 1015 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 1015 may also have one or more anchor points that when engaged can allow the inner stent 1015 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 1017 can compress and/or prevent the modification of the inner stent 1015 prior to the removal of the inner stent covering 1017. In some examples, the inner stent covering 1017 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. The inner stent 1011 can be co-axially related to the outer stent 1015 such that the inner stent 1011 is within the inner radius or diameter of the outer stent 1015.

The main body 1003 can include a body aperture 1019 that allows for access to the internal portions of the main body 1003. In at least one example, the body aperture 1019 is sized and/or configured to allow for the passage and/or storage of one or both stents, a plunger or rod, a firing mechanism (not illustrated), and/or the lead in 1009.

The cover carrier 1021, in some examples a sheath carrier, can allow for a coupling to the one or more sheaths or coverings for the stents of the present disclosure. In at least one example, the covers or sheaths are coupled to the cover carrier 1021 in a manner that when the firing button or tab 1007 is pressed it releases the cover carrier 1021 to move and thereby moving the stent covers or sheaths as well. The cover carrier 1021 may also have a cover carrier engagement aperture that allows portions of the firing tab or button 1007, such as but not limited to firing tab or button extensions 1047 to pass through and/or interact with the cover carrier 1021. In some examples, the cover carrier engagement aperture may be formed in such a way that it must be positioned correctly in order to engage or interact with portion of the firing tab or button 1007, while in other examples, the cover carrier engagement aperture may have a consistent configuration around the entire perimeter of the cover carrier 1021. The cover carrier 1021, in at least one embodiment, can have a cover carrier retention zone. The cover carrier retention zone can be an area to receive a spring or other retention mechanism. In at least one embodiment, the cover carrier retention zone may also be able to engage with a pushing or acceleration mechanism that can push the cover carrier 1021 away from the back stop 1005. The cover carrier retention zone, and/or the cover carrier engagement aperture can surround and/or device a cover carrier pass through void that allows a rod or plunger to pass through the cover carrier 1021.

The lead in 1009 can be coupled to a lead in shaft 1029. The lead in shaft 1029 can be a rod or plunger that passes through the body aperture 1019. In some examples, it can couple with a plunger rod 1031. In at least one example the plunger rod 1031 surrounds the lead in shaft 1029 to provide additional support. In other examples, the plunger rod 1031 can be an extension of the lead in shaft 1029.

In at least on embodiment, a retention mechanism 1033 can be utilized to engage the cover carrier 1021 backwards towards the back stop 1005 or forwards towards the body aperture 1019. In at least one example, the retention mechanism 1033 is a spring, while in other example, other forms of mechanism that can impart kinetic energy may be utilized. When the firing tab or button 1007 is engaged by the user and passes a portion of the firing tab or button through the main body firing tab aperture, the kinetic energy stored in the retention mechanism 1033 can be released.

The retention mechanism 1033 can be coupled between the cover carrier retention zone and the back stop retention zone. The back stop retention zone can be an area to receive a spring or other retention mechanism 1033. In at least one embodiment, the back stop retention zone may also be able to engage with a pushing or acceleration mechanism that can push the cover carrier 1021 away from the back stop 1005. The lead in 1009 interaction depth with a vessel (not illustrated) can be adjusted with a depth adjustment 1035. In at least one example, the depth adjustment 1035 interacts with the back stop 1005 though a threaded connection, while other connections that allow for changes of positioning between two elements would not depart from the spirit of the present disclosure. The threaded connection may be illustrated by a depth adjustment engagement surface along the outer perimeter of the depth adjustment 1035 and the inner perimeter of the back stop 1005.

The lead in shaft 1029, and/or plunger rod 1031 can pass through and/or engage with a back stop aperture defined by the back stop 1005 and/or the depth adjustment aperture defined by the depth adjustment 1035. In at least one example, the back stop aperture can allow for the passage of the lead in shaft 1029 and the plunger rod 1031, while the depth adjustment aperture only allows for the passage of the lead in shaft 1029. Further to this example, the depth of the lead in 1009 engagement with a vessel can be controlled by the amount of the shaft and/or rod that is allowed to pass through them.

FIG. 11A is a partially exploded view illustration of a dual stent delivery tool 1101 in a pre-delivery state 1151A. In at least one embodiment, the dual stent delivery tool 1101 may be utilized to place two stents with a single button press, allowing for the first portion of an amitosis surgery to be completed in just a few seconds, rather than the current methods which can take up to ten to twenty minutes per vessel. In some examples, the dual stent delivery tool 1101 be included as part of a set of delivery tools or in sterilized blister packs that can be opened and utilized in rapid succession during intensive surgery. In at least one embodiment, the pre-delivery state 1151A is the state before a pressure or force 1155 is applied to a firing tab or button 1107. The pre-delivery state 1151A, in at least one example, is the state where the firing tab extensions 1147 are engaged with the cover carrier 1121.

The dual stent delivery tool 1101 can have a main body 1103 for housing the internal workings of the stent delivery tool 1101, and in at least one example, partially housing and/or containing one or more stents. In at least one embodiment, the main body 1103 can be cylindrical, with a first end having a back stop 1105, and a second end opposing the first end, and the second end having an opening to receive the one or more stents. In some examples, the main body 1103 may have additional openings, apertures, or other structures that pass through or along portions of the main body 1103. The back stop 1105 may be threaded, friction fit, or otherwise coupled to the main body 1103 in a manner that prevents it from being removed from the main body 1103 without additional outside forces. The main body 1103 may house all of the components with the exception of portions of the lead in 1109 and/or lead in shaft 1129, firing tab or button 1107, the back stop 1105, and/or depth adjustment 1145.

A firing tab or button 1107 may be utilized by a user or medical professional to activate the mechanisms to transfer one or both of the stents. It would be understood, that while one button is illustrated, in at least one example two or more buttons may be utilized to trigger the transfer and/or insertion of one or more stents, and/or other activities related to these and similar procedures. The firing tab or button 1107 may include firing tab or button engagement extensions 1147 that can engage with the cover carrier 1121. In at least one example, the firing tab or button 1107, when pressed, the firing tab extension 1147 passes through the cover carrier engagement aperture, releasing the cover carrier 1121 and causing it to move. In some examples of the dual stent delivery tool 1101, there may be additional firing tab(s) or button(s) 1107 to allow for vessels to be engaged or disengaged, along with the engagement or disengagement of one or more stents.

When the firing tab 1107 is pressed a lead in 1109, in some examples called an olive tip lead in, can extend or retract based on the design of the dual stent delivery tool 1101. The lead in 1109 can be shaped like a rounded bullet with a tapered front end, coupled to a cylindrical section, and a tapered rear section that coupled to a plunger and/or rod. While the olive shape is illustrated, other shapes may be utilized without departing from the spirit of the present disclosure.

In at least one embodiment, the lead in 1109 can engage and/or interact with an inner stent 1111. In at least one example, the inner stent 1111 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 1111 may also have one or more anchor points that when engaged can allow the inner stent 1111 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 1113 can compress and/or prevent the modification of the inner stent 1111 prior to the removal of the inner stent covering 1113. In some examples, the inner stent covering 1113 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. Similarly, the outer stent 1115 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 1115 may also have one or more anchor points that when engaged can allow the inner stent 1115 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 1117 can compress and/or prevent the modification of the inner stent 1115 prior to the removal of the inner stent covering 1117. In some examples, the inner stent covering 1117 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. The inner stent 1111 can be co-axially related to the outer stent 1115 such that the inner stent 1111 is within the inner radius or diameter of the outer stent 1115.

The main body 1103 can include a body aperture 1119 that allows for access to the internal portions of the main body 1103. In at least one example, the body aperture 1119 is sized and/or configured to allow for the passage and/or storage of one or both stents, a plunger or rod, a firing mechanism (not illustrated), and/or the lead in 1109.

The cover carrier 1121, in some examples a sheath carrier can allow for a coupling to the one or more sheaths or coverings for the stents of the present disclosure. In at least one example, the covers or sheaths are coupled to the cover carrier 1121 in a manner that when the firing button or tab 1107 is pressed, it releases the cover carrier 1121 and causes it to move, thereby moving the stent covers or sheaths as well. The cover carrier 1121 may also have a cover carrier engagement aperture that allows portions of the firing tab or button 1107, such as but not limited to firing tab or button extensions 1147 to pass through and/or interact with the cover carrier 1121. In some examples, the cover carrier engagement aperture may be formed in such a way that it must be positioned correctly in order to engage or interact with portion of the firing tab or button 1107, while in other examples, the cover carrier engagement aperture may have a consistent configuration around the entire perimeter of the cover carrier 1121. The cover carrier 1121, in at least one embodiment, can have a cover carrier retention zone. The cover carrier retention zone can be an area to receive a spring or other retention mechanism. In at least one embodiment, the cover carrier retention zone may also be able to engage with a pushing or acceleration mechanism that can push the cover carrier 1121 away from the back stop 1105. The cover carrier retention zone, and/or the cover carrier engagement aperture can surround and/or device a cover carrier pass through void that allows a rod or plunger to pass through the cover carrier 1121.

The lead in 1109, can be coupled to a lead in shaft 1129. The lead in shaft 1129 can be a rod or plunger that passes through the body aperture 1119. In some examples, it can couple with a plunger rod 1131. In at least one example the plunger rod 1131 surrounds the lead in shaft 1129 to provide additional support. In other examples, the plunger rod 1131 can be an extension of the lead in shaft 1129.

In at least on embodiment, a retention mechanism 1133 can be utilized to engage the cover carrier 1121 backwards towards the back stop 1105 or forwards towards the body aperture 1119. In at least one example, the retention mechanism 1133 is a spring, while in other examples, other forms of mechanism that can impart kinetic energy may be utilized. When the firing tab or button 1107 is engaged by the user and passes a portion of the firing tab or button through the main body firing tab aperture, the kinetic energy stored in the retention mechanism 1133 can be released.

The retention mechanism 1133 can be coupled between the cover carrier retention zone and the back stop retention zone. The back stop retention zone can be an area to receive a spring or other retention mechanism 1133. In at least one embodiment, the back stop retention zone may also be able to engage with a pushing or acceleration mechanism that can push the cover carrier 1121 away from the back stop 1105. The lead in 1109 interaction depth with a vessel (not illustrated) can be adjusted with a depth adjustment 1135. In at least one example, the depth adjustment 1135 interacts with the back stop 1105 though a threaded connection, while other connections that allow for changes of positioning between two elements would not depart from the spirit of the present disclosure. The threaded connection may be illustrated by a depth adjustment engagement surface along the outer perimeter of the depth adjustment 1135, and the inner perimeter of the back stop 1105.

The lead in shaft 1129, and/or plunger rod 1131 can pass through and/or engage with a back stop aperture defined by the back stop 1105, and/or the depth adjustment aperture defined by the depth adjustment 1135. In at least one example, the back stop aperture can allow for the passage of the lead in shaft 1129 and the plunger rod 1131, while the depth adjustment aperture only allows for the passage of the lead in shaft 1129. Further to this example, the depth of the lead in 1109 engagement with a vessel can be controlled by the amount of the shaft and/or rod that is allowed to pass through them.

FIG. 11B is a partially exploded view illustration of a dual stent delivery tool 1101 in a delivered state 1151B. In at least one embodiment, the dual stent delivery tool 1101 may be utilized to place two stents with a single button press, allowing for the first portion of an amitosis surgery to be completed in just a few seconds, rather than the current methods which can take up to ten to twenty minutes per vessel. In some examples, the dual stent delivery tool 1101 can be included as part of a set of delivery tools or in sterilized blister packs that can be opened and utilized in rapid succession during intensive surgery. In at least one embodiment, the delivered state 1151B is the state after a pressure or force is applied to a firing tab or button 1107. The delivered state 1151B, in at least one example, is the state where the firing tab extensions 1147 are disengaged with the cover carrier 1121. Allowing for a movement 1157 to occur that allows the retention mechanism 1133 to be returned to a neutral state and allows the stent(s) to be delivered. When the retention mechanism 1133 returns to a neutral state, the cover carrier 1121 moves with it causing the covers or sheaths of the stent(s) to be removed, allowing them to be placed within and/or around a vessel.

The dual stent delivery tool 1101 can have a main body 1103 for housing the internal workings of the stent delivery tool 1101, and in at least one example, partially housing and/or containing one or more stents. In at least one embodiment, the main body 1103 can be cylindrical, with a first end having a back stop 1105, and a second end opposing the first end, and the second end having an opening to receive the one or more stents. In some examples, the main body 1103 may have additional openings, apertures, or other structures that pass through or along portions of the main body 1103. The back stop 1105 may be threaded, friction fit, or otherwise coupled to the main body 1103 in a manner that prevents it from being removed from the main body 1103 without additional outside forces. The main body 1103 may house all of the components with the exception of portions of the lead in 1109 and/or lead in shaft 1129, firing tab or button 1107, the back stop 1105, and/or depth adjustment 1145.

A firing tab or button 1107 may be utilized by a user or medical professional to activate the mechanisms to transfer one or both of the stents. It would be understood that, while one button is illustrated, in at least one example, two or more buttons may be utilized to trigger the transfer and/or insertion of one or more stents, and/or other activities related to these and similar procedures. The firing tab or button 1107 may include firing tab or button engagement extensions 1147 (illustrated in FIG. 11A) that can engage with the cover carrier 1121. In at least one example, the firing tab or button 1107, when pressed, the firing tab extension 1147 passes through the cover carrier engagement aperture releasing the cover carrier 1121 and causing it to move. In some examples of the dual stent delivery tool 1101, there may be additional firing tab(s) or button(s) 1107 to allow for vessels to be engaged or disengaged, along with the engagement or disengagement of one or more stents.

When the firing tab 1107 is pressed a lead in 1109, in some examples called an olive tip lead in can extend or retract based on the design of the dual stent delivery tool 1101. The lead in 1109 can be shaped like a rounded bullet with a tapered front end, coupled to a cylindrical section, and a tapered rear section that coupled to a plunger and/or rod. While the olive shape is illustrated, other shapes may be utilized without departing from the spirit of the present disclosure.

In at least one embodiment, the lead in 1109 can engage and/or interact with an inner stent 1111. In at least one example, the inner stent 1111 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 1111 may also have one or more anchor points that when engaged can allow the inner stent 1111 to be secured to a vessel (not illustrated). In at least one embodiment, an inner stent covering 1113 can compress and/or prevent the modification of the inner stent 1111 prior to the removal of the inner stent covering 1113. In some examples, the inner stent covering 1113 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. Similarly, the outer stent 1115 can be a modifiable stent that is capable of expanding and/or retracting on itself. In yet other examples, the inner stent 1115 may also have one or more anchor points that, when engaged, can allow the inner stent 1115 to be secured to a vessel (not illustrated). In at least one embodiment, an outer stent covering 1112 can compress and/or prevent the modification of the inner stent 1115 prior to the removal of the outer stent covering 1112. In some examples, the outer stent covering 1112 can be a flexible material with perforations that allow it to be ripped and/or removed in a quick movement without leaving any material behind. The inner stent 1111 can be co-axially related to the outer stent 1115 such that the inner stent 1111 is within the inner radius or diameter of the outer stent 1115.

The main body 1103 can include a body aperture 1119 that allows for access to the internal portions of the main body 1103. In at least one example, the body aperture 1119 is sized and/or configured to allow for the passage and/or storage of one or both stents, a plunger or rod, a firing mechanism (not illustrated), and/or the lead in 1109.

The cover carrier 1121, in some examples a sheath carrier, can allow for a coupling to the one or more sheaths or coverings for the stents of the present disclosure. In at least one example, the covers or sheaths are coupled to the cover carrier 1121 in a manner that when the firing button or tab 1107 is pressed, it releases the cover carrier 1121 and causes it to move, thereby moving the stent covers or sheaths as well. The cover carrier 1121 may also have a cover carrier engagement aperture that allows portions of the firing tab or button 1107, such as but not limited to firing tab or button extensions 1147 (illustrated in FIG. 11A), to pass through and/or interact with the cover carrier 1121. In some examples, the cover carrier engagement aperture may be formed in such a way that it must be positioned correctly in order to engage or interact with portion of the firing tab or button 1107, while in other examples, the cover carrier engagement aperture may have a consistent configuration around the entire perimeter of the cover carrier 1121. The cover carrier 1121, in at least one embodiment, can have a cover carrier retention zone. The cover carrier retention zone can be an area to receive a spring or other retention mechanism. In at least one embodiment, the cover carrier retention zone may also be able to engage with a pushing or acceleration mechanism that can push the cover carrier 1121 away from the back stop 1105. The cover carrier retention zone, and/or the cover carrier engagement aperture can surround and/or device a cover carrier pass through void that allows a rod or plunger to pass through the cover carrier 1121.

The lead in 1109 can be coupled to a lead in shaft 1129. The lead in shaft 1129 can be a rod or plunger that passes through the body aperture 1119. In some examples, it can couple with a plunger rod 1131 (illustrated in FIG. 11A). In at least one example the plunger rod 1131 surrounds the lead in shaft 1129 to provide additional support. In other examples, the plunger rod 1131 can be an extension of the lead in shaft 1129.

In at least on embodiment, a retention mechanism 1133 can be utilized to engage the cover carrier 1121 backwards towards the back stop 1105 or forwards towards the body aperture 1119. In at least one example, the retention mechanism 1133 is a spring, while in other example, other forms of mechanism that can impart kinetic energy may be utilized. When the firing tab or button 1107 is engaged by the user and passes a portion of the firing tab or button through the main body firing tab aperture, the kinetic energy stored in the retention mechanism 1133 can be released.

The retention mechanism 1133 can be coupled between the cover carrier retention zone and the back stop retention zone. The back stop retention zone can be an area to receive a spring or other retention mechanism 1133. In at least one embodiment, the back stop retention zone may also be able to engage with a pushing or acceleration mechanism that can push the cover carrier 1121 away from the back stop 1105. The lead in 1109 interaction depth with a vessel (not illustrated) can be adjusted with a depth adjustment 1135. In at least one example, the depth adjustment 1135 as shown in FIG. 11A interacts with the back stop 1105 though a threaded connection, while other connections that allow for changes of positioning between two elements would not depart from the spirit of the present disclosure. The threaded connection may be illustrated by a depth adjustment engagement surface along the outer perimeter of the depth adjustment 1135 and the inner perimeter of the back stop 1105.

The lead in shaft 1129, and/or plunger rod 1131 can pass through and/or engage with a back stop aperture defined by the back stop 1105, and/or the depth adjustment aperture defined by the depth adjustment 1135. In at least one example, the back stop aperture can allow for the passage of the lead in shaft 1129 and the plunger rod 1131 while the depth adjustment aperture only allows for the passage of the lead in shaft 1129. Further to this example, the depth of the lead in 1109 engagement with a vessel can be controlled by the amount of the shaft and/or rod that is allowed to pass through them.

FIG. 12 is a perspective view illustration of a sheath or cover carrier 1221. The cover carrier 1221 can be coupled to one or more covers or sheaths for one or more stents. These covers or sheaths can couple to any number of points of the cover carrier 1221. The cover carrier engagement aperture 1223 can allow for the positioning of the cover carrier 1221 within a stent delivery system or device. In at least one example, the cover carrier engagement aperture 1223 can be utilized to secure the cover carrier 1221 to a shaft or rod through a fastener, such as, but not limited to, a screw, bolt, or other securing mechanism. The cover carrier retention zone 1225 allows for retention mechanisms, springs, or other kinetic devices to be coupled to the cover carrier 1221. The cover carrier pass-through void 1227, allows for shafts and/or rods to pass through the cover carrier 1221. A cover carrier engagement zone 1253 can be utilized to allow the cover carrier 1221 to engage with a firing tab or button. In at least one example, the cover carrier 1221 can be secured when the cover carrier engagement zone 1253 is engaged, and when released and the cover carrier engagement zone 1253 is not engaged, the cover carrier 1221 is released to move based on the kinetic energy of a securing mechanism.

It should be noted that while vascular, and/or microvascular surgeries and/or surgical methods will be described herein, the present disclosure could also be utilized in any number of surgeries, including, but not limited to those for, the head, neck, sinus, nasal, ear, heart, lung, arteries, veins, brain, nerves, organs, vessels, and/or any other human or animal surgery. While the description will be related to operations on human, it would be understood that those in the veterinarian field could also benefit from the present disclosure. Some examples of the disclosure may also benefit the plumbing, electrical, or other related fields.

Descriptions herein will be made with respect to a gravitational reference, but such descriptions should not be considered limiting. As it would be understood, unless otherwise noted a reference to a left, or right of an object could be mirrored or flipped, similarly unless otherwise noted a reference to up or down could be mirrored or flipped. The stents, and/or stent delivery mechanisms disclosed herein can be manufactured, made, and/or formed with any number of materials, including, but not limited to, wood, plastics, silicon, metal, metal alloys, synthetic materials, polymers, absorbable polymers, Teflon, Mylar, carbon fiber, other like materials, or combinations thereof. In at least one example, the stent of the present disclosure are manufactured and/or constructed of biodegradable materials to allow for the disintegration of the stent within a few days, weeks, or months after delivery, such as, but not limited to 1 day, 2 days, 3 days, 5 days, 1 week, 1.5 weeks, 2 weeks, 2.5 weeks, 3 weeks, 4 weeks, 1 month, 5 weeks, six weeks, 7 weeks, 8 weeks, 2 months, 9 weeks, 10 weeks, 11 weeks, 12 weeks, 3 months, 4 months, 6 months, 9 months, or 12 months.

In some versions, the body of a stent is a hollow cylinder, hollow tubular body, or other hollow structure that may have an inner diameter and corresponding inner circumference, and an outer diameter and corresponding outer circumference. The stents of the present disclosure may also include an aperture on one or more ends defined by the body of the stent and more particularly by the inner diameter, and/or inner circumference of the stent. It would be understood that the aperture(s) can have many cross-sections and/or profiles, such as but not limited to, a circle, an oval, a square, a rectangle, a polygon, a cone, a pyramid, other shapes or profiles, and/or combinations thereof. In one example, the body of the stent(s) may have a top, and a bottom that can be in planes parallel to each other, and a first end, and a second end, wherein the second end is distal from the first end. In alternative examples, the top and bottom of the body of the stent may not be in parallel planes. For example, a vessel may have a narrowed or narrowing section that requires the body of the stent to be smaller at one end, and larger at the other end. Creating a situation where the top would be in a plane that converges with a plane parallel to the bottom of the body of the stent.

Additionally, in at least one version, the stent may include sections that fore the stent body, and each of the stent body sections may be constructed of a different material. The different materials can allow for different expansion or deformation rates for each stent body section for an expandable or modifiable stent. The stent body sections can also be a first stent end section (proximal section), a central stent section (attachment section), and a second stent end section (distal section). It would be understood that the proximal and distal sections may also be reversed in some examples. Each of the end sections may also have their own proximal, attachment, and/or distal sections.

The compression of a modifiable stent can be generated by the materials utilized to form, construct, and/or manufacture the stent. The materials can have an elasticity, or tensile strength based on the modular, sectional, and/or geometrical structure chosen for the specific stent. The modifiable stent body may also have atraumatic anchor(s), and/or traumatic anchor(s) that may be modifiable as well. A device can be utilized to deliver the stent to a donor and/or recipient vessel and initiate a decompression, expansion, and/or modification of the stent properties, the stent body, and/or anchor(s).

The stents of the present disclosure may include a modifiable structure that may be manufactured of a material, such as plastics, silicon, metal, metal alloys, synthetic materials, polymers, absorbable polymers, Teflon, Mylar, carbon fiber, other like materials, or combinations thereof. The material can allow for the modifiable structure to be approximately one-half its normal size, be approximately one-quarter of its normal size, or any other fraction of one whole portion of the modifiable structure. The modifiable structure may also be formed, constructed, and/or manufactured utilizing a material that may have a memory effect or expansion memory such as a pliable plastic or silicon material, but other materials such as plastics, silicon, metal, metal alloys, synthetic materials, polymers, absorbable polymers, Teflon, Mylar, carbon fiber, other like materials, or combinations thereof, may also be utilized. A memory effect or expansion memory can be described as a material that can be manipulated from a first position to a second position and then return to the first position upon release from the second position.

The structure node can provide a connection point for the expandable structure. In at least one example the structure node may be utilized with the expandable structure to create a mesh of nodes. The structure node may be constructed, formed, or manufactured utilizing a material such as, but not limited to, plastics, silicon, metal, metal alloys, synthetic materials, polymers, absorbable polymers, Teflon, Mylar, carbon fiber, other like materials, or combinations thereof. In at least one example, the structure node can be constructed, formed, and/or manufactured with the expandable structure. In alternative examples, the structure node may be connected to, or affixed to the expandable structure through an adhesive, fastener, glue, connector, cement, epoxy, binder,

In at least one example, the expandable or modifiable member and/or expandable connection node can be manufactured with magnetic, and/or shape memory properties. In at least one example, the connection node may interact with other connection nodes to cause a transformation or modification of expandable or structural member.

The expandable structure element, can be formed, constructed, and/or manufactured utilizing materials, such as, but not limited to, plastics, silicon, metal, metal alloys, synthetic materials, polymers, absorbable polymers, Teflon, Mylar, carbon fiber, other like materials, or combinations thereof. Additionally, the expandable structure element, in one example, may also have a memory effect that can allow the expandable structure element to compressed or stretched from a first position to a second position, and then upon release from the second position to return to the first position.

In alternative examples, the connection node can be formed, constructed, and/or manufactured of a different material than the expandable structure element. The non-expandable structure element may be formed, constructed, and/or manufactured utilizing materials, such as, but not limited to plastics, silicon, metal, metal alloys, synthetic materials, polymers, absorbable polymers, Teflon, Mylar, carbon fiber, other like materials, or combinations thereof. In at least one example, a section of a stent apparatus or a first or second end of a stent apparatus, having a proximal end section, an attachment end section, and a distal end section that can couple to a hollow tubular section or structure of the stent apparatus. An expansion may include a linear expansion or radial expansion.

A cover or sheath that encloses the modifiable stent can maintain the unmodified state, or the properties of the stent elements may be modified to create a memory effect. The stent elements may also be interconnected elements or interconnecting elements. These properties can include, but are not limited to, the chemical structure, magnetic structure, and/or electrical conductivity structure of stent elements. These properties can be modified, to change the geometry of the modifiable stent to a modified state. For example, the transition from an unmodified state to a modified state, can allow for an expansion of the modifiable stent to secure it to the lumen or wall of a vessel, or set of vessels.

The sheath, cover, or transport device may be coupled to a needle to assist in removal of the sheath, cover, or transport device after placing the expandable stent body in a proper location. In one example, the needle removes the sheath, cover, or transport device from a proximal end of the stent body. A donor vessel, and/or a recipient vessel can receive the expandable stent.

The expandable stent can be expanded in an accordion, twisting, and/or turning motion. In other examples, the at least one atraumatic anchor(s) can be pliable and/or flexible, allowing one or both ends of the stent to be placed within a vessel (not illustrated) without an expansion, and/or delivery tool.

The stents of the present disclosure may comprise spike(s), barb(s), atraumatic anchor(s), prong(s), point(s), pin(s), and/or any combination(s) thereof along an inner or outer surface of the stent. The anchors may be atraumatic or non-puncturing, or a form of puncturing or traumatic anchor. For example, in a low pressure or slow blood flow vessel atraumatic anchors may be used to avoid damage to the vessels with low blood flow through them. In another example, the stent(s) may be utilized in a high pressure or fast blood flow vessel utilizing the anchors to secure the stent in place through the use of a puncturing anchor and/or a combination of puncturing and atraumatic anchors.

During surgeries that allow for end-to-end anastomoses the donor vessel and the recipient vessel can be affixed to the stent via the stent anchor(s) and/or the stent end anchor(s). The vessels do not have to be prepared in a traditional manner because the anchor(s) allow for the securing of the donor vessel and/or the recipient vessel with no need for suturing of the vessels. There is also a decrease in the amount of time required preparing the ends of the vessels. The stent body anchor(s) can be manufactured with a length sufficient to puncture through the lumen or wall of both the donor vessel and the recipient vessel. Similarly, the stent end anchor(s) can be manufactured with a length sufficient to puncture through the lumen or wall of the donor vessel or the recipient vessel. Traumatic anchor(s) would reference an anchor that can puncture or be invasive to the wall or lumen of a vessel, but this would be an acceptable level of injury and/or be minimally invasive to secure the stent in place within a donor and/or recipient vessel. The atraumatic anchor(s) and/or traumatic anchor(s) may be in a compressed or unexpanded state prior to and during initial delivery or installation of the stent.

While this disclosure has been particularly shown and described with reference to preferred embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention. The inventors expect skilled artisans to employ such variations as appropriate, and the inventors intend the invention to be practiced otherwise than as specifically described herein. Accordingly, this disclosure includes all modifications and equivalents of the subject matter recited in the claims appended hereto as permitted by applicable law. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the disclosure unless otherwise indicated herein or otherwise clearly contradicted by context.

While various embodiments in accordance with the principles disclosed herein have been described above, it should be understood that they have been presented by way of example only, and not limitation. Thus, the breadth and scope of this disclosure should not be limited by any of the above-described exemplary embodiments but should be defined only in accordance with any claims and their equivalents issuing from this disclosure. Furthermore, the above advantages and features are provided in described embodiments but shall not limit the application of such issued claims to processes and structures accomplishing any or all of the above advantages.

Additionally, the section headings herein are provided for consistency with the suggestions under 37 C.F.R. 1.77 or otherwise to provide organizational cues. These headings shall not limit or characterize the invention(s) set out in any claims that may issue from this disclosure. Specifically, and by way of example, although the headings refer to a “Technical Field,” the claims should not be limited by the language chosen under this heading to describe the so-called field. Further, a description of a technology as background information is not to be construed as an admission that certain technology is prior art to any embodiment(s) in this disclosure. Neither is the “Brief Summary” to be considered as a characterization of the embodiment(s) set forth in issued claims. Furthermore, any reference in this disclosure to “invention” in the singular should not be used to argue that there is only a single point of novelty in this disclosure. Multiple embodiments may be set forth according to the limitations of the multiple claims issuing from this disclosure, and such claims accordingly define the embodiment(s), and their equivalents, that are protected thereby. In all instances, the scope of such claims shall be considered on their own merits in light of this disclosure but should not be constrained by the headings set forth herein. 

1. A dual stent delivery system comprising: a delivery tool with a main body having a first end and a second end; a back stop removably coupled to the second end of the main body; a body aperture defined by the first end of the main body; a shaft passing through the body aperture, a cover carrier with a void that allows for the passage of the shaft through the cover carrier; a retention mechanism coupled to the back stop and the cover carrier; and a firing button that is removably engaged with the cover carrier until a force is applied to it such that the cover carrier moves towards the backstop; a modifiable stent coaxially positioned around the shaft with a modifiable stent cover surrounding the modifiable stent; and a coil stent coaxially positioned around the shaft, the modifiable stent, and a coil stent cover that is positioned closer to the shaft than the coil stent.
 2. (canceled)
 3. The dual stent delivery system of claim 1, wherein the deliver tool is generally cylindrical.
 4. The dual stent delivery system of claim 1, the firing button causes a potential energy of the retention mechanism to be converted into a kinetic energy when the force is applied to the firing button.
 5. The dual stent deliver system of claim 1, wherein the modifiable stent expands radially outward after the firing button has the force applied to it.
 6. The dual stent delivery system of claim 1, wherein the coil stent retracts radially inward after the firing button has the force applied to it.
 7. A stent delivery system comprising: a combination tool; a compressible stent; a coil stent; and a tweezer tool; wherein the combination tool receives a first end of the compressible stent, and a portion of the tweezer tool, and the tweezer tool engages a first end of the coil stent.
 8. The stent delivery system of claim 7, wherein the combination tool is configured to receiving at least a first end of the compressible stent.
 9. The stent delivery system of claim 7, wherein the combination tool further comprises a stent receiving aperture.
 10. The stent delivery system of claim 7, wherein the combination tool further comprises at stent receiving channel.
 11. The stent delivery system of claim 7, wherein the combination tool further comprises a stent deployment point.
 12. The stent delivery system of claim 7, wherein the combination tool further comprises a handle.
 13. The stent delivery system of claim 7, wherein the combination tool further comprises a main body.
 14. The stent delivery system of claim 7, wherein the compressible stent is contained within a sheath.
 15. The stent delivery system of claim 14, wherein the combination tool engages the sheath to allow for complete removal of the sheath from the stent.
 16. The stent delivery system of claim 7, wherein the combination tool receives at least a first end of the compressible stent.
 17. The stent delivery system of claim 7, wherein the combination tool receiving at least a first end of the compressible stent within a main body of the combination tool.
 18. The stent delivery system of claim 7, wherein the combination tool engages with a first end of the tweezer tool.
 19. The stent delivery system of claim 7, wherein the combination tool engages with a first end of the tweezer tool at a stent receiving aperture.
 20. The stent delivery system of claim 7, wherein the compressible stent is coaxial to the tweezer tool that is at least partially coaxial to the combination tool at a first end of the tweezer tool, and the tweezer tool is coaxial to the coil stent at a second end of the tweezer tool.
 21. The stent delivery system of claim 7, wherein the combination tool further comprises a main body configured to receive a portion of the compressible stent with a stent receiving channel, and the combination tool engages the compressible stent with a stent deployment point; wherein the combination tool engages with a first end of the tweezer tool at a stent receiving aperture; and wherein the tweezer tool is engages with the compressible stent to apply a compression force to it, while providing an engagement surface for the coil stent at a second end of the tweezer tool. 